KR101140295B1 - Hybrid seal ring apparatus for turbine - Google Patents

Abstract

PURPOSE: A hybrid sealing device for a turbine is provided to prevent a mechanical load of the turbine by preventing resonance because the water flows to the longitudinal direction of a rotor unit with passing through an anti-swirl portion. CONSTITUTION: A sealing unit(40) of a hybrid sealing device for a turbine(100) comprises a labyrinth unit(50), a brush unit(60) and an anti-swirl unit(70) The labyrinth unit surrounds an outer surface of a rotor portion. The labyrinth unit has a tooth and bristle connection groove. The tooth blocks water flowing along the outer surface of the rotor portion. A plurality of bristles of brush unit is inserted into the bristle connection groove with surrounding the outer surface of the rotor portion. The end of the bristle is contacted with the outer surface of the rotor portion. The anti swirl part is formed in the backend of the labyrinth unit and surrounds the outer circumference of the rotor portion. A blade of the anti swirl part is protruded downward, formed at fixed intervals.

Description

Hybrid sealing ring apparatus for turbine

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a turbine sealing apparatus, and more particularly, to a hybrid sealing apparatus for a turbine that effectively seals a space between a rotor portion and a casing, and minimizes vibration of the turbine to improve power generation efficiency.

Generally, a turbine refers to a machine that converts energy of a fluid such as water, gas, and steam into useful mechanical work. That is, a turbo type machine which plants several blades or blades on the circumference of the rotating body and spouts steam or gas thereon and rotates at high speed is called a turbine. As the industry develops, turbines such as steam turbines and gas turbines are becoming larger, higher, and higher in pressure.

In the turbine, since the leakage of steam generated in the seal between the rotor and the stator is a major factor in increasing the fuel cost by decreasing the efficiency of the turbine, the design of a sealing technique, that is, a seal ring device to reduce the steam leakage Technology is very important.

That is, the sealing device is a stainless steel sealing device used for gas, steam power, high pressure and high pressure turbine to prevent leakage of gas, steam and the like to maximize the efficiency of generator energy production and to prevent vibration of the rotor. Play a role.

1 is a cross-sectional view showing a state in which a general sealing device is mounted on a turbine.

As shown in FIG. 1, the general sealing device 5 is provided in the outer ring and the inner ring of the diaphragm 3 attached to the casing 2.

2 is a cross-sectional view showing a general labyrinth type sealing device.

As shown in FIG. 2, the sealing device 5 is of a labyrinth-type with a sharp tooth 6 which is widely used as a non-contact annular seal of a turbine, and is a fluid flowing in the turbine. The leakage flow rate of the fluid is reduced by using the Throttling Process of the fluid, and the pressure drop effect occurs in the process of repeating the expansion and expansion of the tooth 6 by sequentially arranging the tooth 6 to the stator. Will be reduced.

However, when the space is sealed using the labyrinth type sealing device 5, the efficiency loss caused by the fluid leaking into the gap between the rotor unit 1 and the sealing device 5 is a loss of the overall turbine efficiency. Accounted for over 33% of the total.

This can reduce the loss of steam leakage by forming a small gap between the sealing device 5 and the rotor part 1, but the gap is reduced due to vibration or thermal unbalance deformation of the rotor part 1. When rubbing occurs due to the sealing device 5 and the rotor part 1 contacting each other, the tooth 6 of the sealing device 5 wears out, and thus the sealing action decreases over time. there was.

That is, since a relatively large vibration may occur at the time of starting compared with the normal operation, the clearance between the rotor unit 1 and the sealing device 5 should be more than a certain distance. However, the larger the gap between the sealing device 5 and the rotor unit 1 is, the more the leakage of the fluid increases, so that the sealing effect is reduced, resulting in more efficiency loss of the turbine.

In order to solve the above problems, the present invention solves the problem to provide a hybrid sealing device for a turbine that effectively seals the space between the rotor portion and the casing, prevents the swirl phenomenon to prevent vibration and improve the power generation efficiency. It is a task.

In order to solve the above problems, the present invention is provided with a sealing portion for sealing the flow of fluid leaking between the casing of the turbine and the rotating rotor portion, and protruded on the upper side of the sealing portion, along the connection portion of the casing inner periphery It includes a coupling portion connected to the coupling groove formed, the sealing portion is provided so as to surround the outer peripheral surface of the rotor portion bristle coupling groove is formed in the center, the outer circumference of the rotor portion on the front and rear sides based on the bristle coupling groove, respectively A labyrinth unit including a first labyrinth unit and a second labyrinth unit having a protruding tooth to block the flow of the fluid; A brush part having a plurality of bristles disposed and fixed to the coupling groove to surround the outer circumferential surface of the rotor part, the ends of which are disposed to contact the outer circumferential surface of the rotor part; And an antiswirl portion provided on the front side of the labyrinth portion to surround the outer circumferential surface of the rotor portion and having wing portions protruding downward at spaced intervals.

Here, the tooth is provided with a first surface opposed to the inflow side of the fluid and a second surface opposite to the first surface, the first surface is formed perpendicular to the inflow side direction of the fluid, Two sides are formed to be inclined.

Then, the flow of the fluid flowing along the rotational direction of the rotor portion is rectified by the first rectification in the anti-swirl portion, and rectified by the second rectification in the first labyrinth portion, and rectified by the third portion in the brush portion. In the second labyrinth unit, it is preferable that the rectification is performed by the fourth order.

In addition, the brush portion is fixed to the bristle by the electron beam point, it is preferable that the brush fixing portion formed with a bristle support extending to have a step with the rotor portion on both sides of the fixed support for the bristle.

Further, the anti-swirl portion is connected to one side of the labyrinth portion, a plurality of wings having an induction angle in the direction opposite to the swirl flow of the fluid to guide the flow of the fluid flowing along the rotational direction of the rotor in the longitudinal direction It is preferred to be provided.

Through the above solution, the hybrid sealing apparatus for a turbine of the present invention provides the following effects.

 First, since the sealing between the rotor portion and the casing using the hybrid sealing device for a turbine having a complex sealing effect of the present invention, the sealing efficiency of the sealing portion is increased as a compact volume, thereby significantly increasing the power generation efficiency of the turbine.

Second, since the brush portion is provided in contact with the outer surface of the rotor portion to seal the gap gap between the rotor portion and the sealing portion, it is possible to more effectively seal the leakage of fluid that may occur in the gap difference to increase the power generation efficiency Can be.

Third, due to viscosity, the fluid flowing along the rotational direction of the rotor portion is passed through the anti-swirl portion to induce the flow in the longitudinal direction of the rotor portion, and thus a resonance phenomenon occurs due to the overlap of the fluid having a frequency in the rotational direction of the rotor portion. Since it is possible to prevent the vibration by reducing the mechanical load of the turbine to prevent the failure of the turbine.

Fourth, the first surface and the second surface of the tooth is formed to be inclined, or as the first surface is vertically disposed, the gap formed between the rotor portion and the end of the tooth is close to each other to flow the fluid flowing between the gaps. It can effectively block, and the first surface provided on the inlet side serves as a blocking wall to block the flow of the fluid and at the same time to form a vortex to interrupt the flow of the fluid, thereby significantly reducing the amount of the leaked fluid of the turbine The power generation efficiency can be increased.

Fifth, since the tooth is inclined to the inlet side and deformed toward the outlet side by local stress of the fluid, the gap between the rotor and the sealing portion can be maintained so that the end of the tooth is in contact with the rotor. It is possible to significantly improve the service life of the sealing device by maintaining the sealing effect by preventing the wear phenomenon.

1 is a cross-sectional view showing a state in which a general sealing device is mounted on a turbine.
Figure 2 is a cross-sectional view showing a general labyrinth type sealing device.
3 is a cross-sectional view showing a state in which a hybrid seal device for a power turbine according to a first embodiment of the present invention is mounted to surround a rotor part.
Figure 4 is a schematic perspective view showing a hybrid sealing device for a turbine according to a first embodiment of the present invention.
5 is a cross-sectional view showing a hybrid sealing device for a turbine according to a first embodiment of the present invention.

Hereinafter, a hybrid sealing apparatus for a turbine according to a preferred embodiment of the present invention with reference to the accompanying drawings will be described in detail.

3 is a cross-sectional view showing a state in which a hybrid seal device for a power turbine according to a first embodiment of the present invention is mounted to surround a rotor part.

As shown in FIG. 3, a sealing part 40 for sealing a flow of fluid leaked between the casing 20 of the turbine and the rotating rotor part 10 and a protrusion protruding from the upper part of the sealing part 40 are provided. However, it is preferable that the coupling part 30 is connected to the coupling groove 21 formed along the connection part 25 formed along the inner circumference of the casing 20.

Here, the connection portion 25 is preferably mounted or coupled to the casing 20, such as a diaphragm, including the casing 20, and includes all the structures that are integrally provided, the coupling groove 21 is It is preferable to be provided inside all the structures forming the connection portion 25.

Similarly, the mounting position of the sealing portion 40 is not limited, it is preferable to be understood that it can be mounted in any place where the sealing between the rotating rotor portion 10 and the fixed casing 20 is required. .

As shown in the arrow shown in Figure 3, the majority of the steam or gas introduced into the casing 20 passes through the partition 27 of the fixed diaphragm while extending to the side of the rotor portion 10 is provided with a rotary blade The 27a is rotated and flows again by the partition 27 to the next rotary vane 27a to be rotated and finally discharged to the outside. In this process, when the rotary blades 27a rotate, the rotor unit 10 including the rotary blades 27a rotates to generate power.

At this time, the coupling portion 25 is preferably formed with the coupling groove 21 along the outer circumference thereof so that the sealing portion 40 is fixedly mounted, the coupling provided to protrude along the outer circumference of the sealing portion 40 The portion 30 is formed to correspond to the shape of the coupling groove 21 is fitted and fixed to the coupling groove 21.

Here, the turbine hybrid sealing apparatus 100 will be described in detail with reference to FIGS. 4 to 5.

4 is a schematic perspective view showing a hybrid sealing device for a turbine according to a first embodiment of the present invention, Figure 5 is a cross-sectional view showing a hybrid sealing device for a turbine according to a first embodiment of the present invention.

As shown in FIG. 4, the sealing part 40 of the hybrid sealing device 100 for a turbine according to the present invention is a labyrinth part 50, a brush part 60, and an anti-swirl part. , 70).

Here, the brush portion 60, labyrinth portion 50 and the anti-swirl portion 70 constituting the sealing portion 40 is a high-temperature safe material, especially iron, containing nickel, chromium, cobalt, etc. It is preferably made of a material such as an alloy or a copper base alloy.

Therefore, the sealing part 40 may have stability to heat generated by friction between the rotor part 10 and the diaphragm 3 by the rotation of the rotor part 10, and may be made of a flexible material. Since the friction with the rotor unit 10 also occurs, the rotor unit 10 may not be worn, thereby reducing the amount of leakage fluid and improving safety in driving.

First, the labyrinth unit 50 includes a first labyrinth unit 51, a second labyrinth unit 52, a tooth 55, and a bristle coupling groove 53.

In detail, the labyrinth part 50 is provided to surround the outer circumferential surface of the rotor part 10, and the tooth 55 protrudes to block the flow of the fluid flowing through the outer circumference of the rotor part 10. The bristle coupling groove 53 is preferably formed.

Here, the first labyrinth unit 51 is formed in the inlet portion 41 of the high-pressure region in which fluid such as steam or gas flows into the sealing unit 40, and the second labyrinth unit 52 is The fluid is formed in the outlet portion 42 of the low pressure region flowing out of the sealing portion 40.

At this time, the first labyrinth unit 51 and the second labyrinth unit 52 may be provided integrally extending, caulking, etc. after each of the first and second labyrinth unit (51, 52) It can be provided by a combination of.

In addition, the first and second labyrinth parts 51 and 52 are provided to surround the outer circumference of the rotor part 10, and the plurality of toothes protruded with a predetermined step with the rotor part 10. 55).

Here, the tooth 55 is provided with a tapered protrusion below the sealing surface 54 of the inner circumference of the first and second labyrinth parts 51 and 52, and a plurality of the tooth 55 are formed by the fluid. A plurality of passing stages 56 is formed.

In this case, the rotor portion 10 opposite to the tooth 55 may also have a protrusion 11, and the protrusion 11 may maintain a constant gap between the tooth 55 and the rotor portion 10. The height of the tooth 55 is also reduced by the height of the formation.

On the other hand, the wear of the tooth 10 is easier to wear than the rotor 10 so that the material of the tooth 55 to match the material of the body body or lower than the material of the rotor 10 in order to prevent damage It is preferable to be made of a material having a hardness characteristic value.

In this case, the tooth 55 is generally provided along the outer circumference of the rotor part 10, and in the case of sealing the high pressure part, the tooth 55 may be installed in a direction perpendicular to the rotor part 10.

The tooth 55 includes a first surface 58 facing the inflow side of the fluid and a second surface 59 opposite to the first surface, wherein the first surface 58 and the first surface 58 are provided. At least one side of the two surfaces 59 is preferably formed to be inclined, which will be described later based on other embodiments.

The labyrinth portion 50 is arranged in the longitudinal direction of the rotor portion 10 by arranging a relatively large number of the teeth 55 for the fluid flow from the inlet portion 41 to the outlet portion 42. The fluid to flow in parallel flows along the winding path between the tooth 50 and the stage 56.

In this case, the stage 56 is formed by arranging the teeth 55 in order. Here, the fluid is throttled when passing through the narrow portion formed by the step between the tooth 55 and the rotor part 10, and the vortex phenomenon occurs in the stage 56 to decrease the pressure. Since the pressure of the leaking fluid is reduced while the action is continued, the leakage of the fluid is prevented due to the pressure drop indicating the pressure difference between the inlet 41 and the outlet 42.

On the other hand, the brush unit 60 includes a bristle fixing part 62, a bristle support 63, bristle 65.

In detail, the brush part 60 is inserted into and fixed to the bristle coupling groove 53 to surround the outer circumferential surface of the rotor part 10, and the end portion is disposed to contact the outer circumferential surface of the rotor part 10. A plurality of bristle 65 is provided.

In addition, the brush unit 60 is fixed by electron beam welding (EBW) using an electron beam, the plurality of bristle 65 is fixed by pressing the inside of the bristle fixing part 62 desirable. The bristle fixing part 62 may include a receiving part accommodating one end of the bristle 65, and both sides of the receiving part may be extended to form the bristle support 63. At this time, the bristle support 63 is preferably provided with a narrow step with the rotor portion 10.

That is, the labyrinth unit 50 is fitted into the coupling groove 21 of the diaphragm 3, the rotor unit 10 is coupled to form a step of a predetermined interval, the brush unit 60 Is fitted into the bristle coupling groove 53, the labyrinth portion 50 and the rotor portion 10 is provided with a bristle extension portion 66 or more of the step formed by the end portion of the bristle 65 It is disposed in contact with the outer circumference of the rotor portion 10 that rotates.

As a result, a seal is formed between the rotor part 10 and the sealing part 40, thereby preventing noise and smooth rotation of the rotor part 10, and in the sealing part 40. The deflection force due to the pressure of the fluid is overcome.

Meanwhile, the bristle 65 may interfere with the tooth 55 while being deformed to correspond to the rotational direction by the rotating rotor part 10. The bristle coupling groove 53 The bristle support 63 extending above and stepped with the rotor part 10 is fixed and restrained along both circumferential directions of the bristle 65 to prevent interference. Here, the step formed by the bristle support 63 may correspond to the height of the step formed by the tooth 55 and the rotor part 10.

In addition, the bristle support 63 is provided between the labyrinth unit 50 and the brush unit 60 to form a step with the rotor unit 10, so that the stage (like the tooth 55) 56 may also serve to form.

Meanwhile, the fluid passing through the labyrinth part 50 and the brush part 60 vibrates by a uniform flow of the fluid, and thus a phenomenon that follows the rotational direction of the rotor part 10 occurs. When the amount of the vibrating fluid is increased, vibrations of the fluid may overlap and resonance may occur between the sealing parts 40. In order to prevent this, the front inlet part of the labyrinth part 50 ( 41, the anti-swirl portion 70 is further included.

Here, the anti-swirl portion 70 comprises an extension portion 75 and the wing portion 71.

In detail, the anti-swirl portion 70 is provided to surround the outer circumferential surface of the rotor portion 10 on the square side of the labyrinth portion 50 of the inlet portion side, the wing portion 71 protruding downward at spaced intervals ) Is formed, and like the labyrinth part 50, the rotor part 10 is formed to have a predetermined step, and is preferably made of a soft metal so as not to damage the outer circumference of the rotor part 10.

Here, the anti-swirl portion 70 is an extension portion 75 is formed from one side of the labyrinth portion 50, the wing portion 71 is formed on the integrally extended extension portion 75 It is preferably made of, but may be combined by welding or the like by making a separate packing ring (packing ring).

On the other hand, the anti-swirl portion 70 has an induction angle opposite to the flow of the fluid to guide the flow of the fluid flowing along the rotational direction of the rotor portion 10 in the longitudinal direction of the rotor portion 10. Branches are provided with a plurality of the wings 71.

Here, the wing portion 71 is provided by cutting the extension portion 75 to have an induction angle twisted at a predetermined angle in a direction opposite to the direction in which the fluid follows the rotational direction of the rotor portion 10. .

Accordingly, the fluid passing through the labyrinth part 50 and the brush part 60 rotates along the rotational direction of the rotor part 10. The fluid part has the wing part 71 having the induction angle. When passed through, the flow of the fluid is switched in the longitudinal direction of the rotor part 10.

As a result, the fluid switched in the longitudinal direction passes through the anti-swirl portion 70 provided later, thereby not generating a resonance phenomenon, thereby preventing a mechanical load on the turbine.

Here, the anti-swirl portion 70 may form an induction hole through the extension portion 75 so as to have a constant induction angle in a direction opposite to the flow direction of the fluid instead of forming the wing portion 71. Do. At this time, the induction hole may serve to control to direct the flow of the fluid, such as the wing portion (71).

On the other hand, it is easy to understand the process and the sealing effect of the hybrid sealing device for the turbine 100 is sealed between the rotor unit 10 and the casing 20 with reference to FIGS.

As shown in FIGS. 3 to 5, the turbine hybrid sealing device 100 is connected to the connecting portion 25 to seal the flow of fluid lost between the rotating rotor portion 10 and the fixed casing 20. The coupling part 30 is fixedly coupled to the coupling groove 21 provided along the inner circumference of the blade.

Here, the sealing portion 40 is provided along the outer periphery of the rotor portion 10, the inlet portion 41 is disposed in the high pressure region through which the fluid flows, the outlet portion 42 to the low pressure region Is placed.

In addition, the fluid flowing from the inlet part 41 is first rectified and directly rectified through the anti-swirl part 70 to the inlet part 41, and then the first of the labyrinth part 50. It passes through the labyrinth unit 51. At this time, the fluid introduced into the anti-swirl portion 70 guides the traveling direction of the fluid by the wing portion to correspond to the longitudinal direction of the rotor portion 10 to pass through the anti-swirl portion 70. The fluid flows as if the fluid wraps along the rotational direction of the rotor unit 10, thereby providing an effect of preventing resonance caused by amplification.

In addition, the fluid flows into the stage 56 formed by the plurality of teeth 55 protruding in a step with the rotor part 10 in an inner direction of the first labyrinth part 51. As it passes through the stage 56, a portion of the fluid is sealed by the throttling action to lower the pressure primarily.

On the other hand, the fluid passing through the first labyrinth portion 51 is moved to the brush portion 60 side, the brush portion 60 is in contact with the rotor portion 10 is provided with the bristle (65) Sealing the step so that the fluid leaking due to the step between the first labyrinth part 51 and the rotor part 10 may be secondarily sealed, and the fluid leaked in the step may be more effectively sealed. And, it provides an effect of absorbing the vibration of the rotor unit 10.

In addition, the leaked fluid that has passed through the brush part 60 flows into the second labyrinth part 52, and the stage is formed by the tooth 55 as in the first labyrinth part 51. The fluid is third-sealed by throttling as it passes through 56 in turn.

As described above, the fluid flowing along the rotational direction of the rotor unit 10 passes through the anti-swirl unit 70 which guides in the longitudinal direction of the rotor unit 10 to prevent resonance of the fluid. The mechanical load of the turbine can be prevented, and the fluid passing through the sealing part 40 effectively seals the fluid generated by leaking through the labyrinth part 50 and the brush part 60 to the turbine. The efficiency can be improved.

In addition, the swirl flow of the fluid flowing along the rotational direction of the rotor portion 10 is rectified by the primary rectification in the anti-swirl portion, and rectified by the secondary rectification in the first labyrinth portion, the brush portion In the third rectified rectified in, it is preferred that the fourth rectified in the second labyrinth part is straightened. Of course, the arrangement order of the configuration for the first to fourth order rectification can be changed within the scope of the technical idea of the present invention. Here, referring to FIG. 3, the "rectified and straightened" refers to a process in which the flow is purified so that the swirl flow of the fluid flowing helically along the rotational direction of the rotor part 10 is straightened in the axial direction of the rotor part. You will see that it means.

In detail, the fluid flows along the rotational direction of the rotor unit 10, and the anti-swirl unit 70 provided without a spacing next to the rectifier may rectify the flow of the fluid to direct the fluid. Thereafter, the rotor part rotates due to a biasing force with respect to the rotor part 10 that rotates while passing through the first labyrinth part 51 with a predetermined viscosity introduced through the inlet part 41. It flows along the direction, and the brush part 60 seals the flow of the fluid, and the rectification is performed by the bristle 65 arranged in a bundle.

As described above, the present invention is not limited to the above-described embodiments, but may be modified by those skilled in the art without departing from the scope of the claims of the present invention. Such modifications are within the scope of the present invention.

10: rotor part 11: protrusion part
2, 20: casing 21: coupling groove
25: connector 27: partition
27a: rotary wing 30: coupling portion
40: sealing part 41: inlet part
42: outlet 50: labyrinth
51: first labyrinth unit 52: second labyrinth unit
53: Bristol Union Home 55: Tooth
56: stage 58: first page
59: second page 60: brush part
62: Bristol fixing 63: Bristol support
65 Bristol 66 Bristol Extension
70: anti-swirl 71: wings
75: wing portion 100: hybrid sealing device

Claims (5)

Sealing part for sealing the flow of fluid leaked between the casing of the turbine and the rotating rotor portion, and provided to protrude to the upper side of the sealing portion, the coupling portion connected to the coupling groove formed along the connection portion of the casing inner circumference, The sealing part
It is provided to surround the outer peripheral surface of the rotor portion is formed bristle coupling groove in the center, protruding tooth is provided on the front and rear sides to block the flow of the fluid flowing through the outer periphery, respectively, based on the bristle coupling groove A labyrinth unit comprising a first labyrinth unit and a second labyrinth unit;
A brush part having a plurality of bristles disposed and fixed to the coupling groove to surround the outer circumferential surface of the rotor part, the ends of which are disposed to contact the outer circumferential surface of the rotor part; And
The hybrid sealing device for a turbine provided on the front side of the labyrinth portion to surround the outer peripheral surface of the rotor portion, comprising an anti-swirl portion protruding downwardly spaced apart. The method of claim 1,
The tooth is provided with a first surface facing the inflow side of the fluid and a second surface opposite to the first surface, the first surface being formed perpendicular to the inflow side direction of the fluid, the second surface Hybrid sealing device for a turbine, characterized in that formed inclined. delete The method of claim 1,
Wherein the brush portion is fixed to the bristle by electron beam welding, a hybrid fixing for a turbine characterized in that the bristle support is formed with a bristle support extending to have a step with the rotor portion on both sides fixed to support the bristle Device. The method of claim 1,
The anti-swirl portion is connected to one side of the labyrinth portion, it is provided with a plurality of wings having an induction angle in the direction opposite to the swirl flow of the fluid to induce a longitudinal flow of the fluid flowing along the rotation direction of the rotor portion Hybrid sealing device for a turbine.

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