KR101638480B1 - brush sealing apparatus for turbine - Google Patents

Abstract

In order to improve the sealing performance and the durability of the product for fluid flowing between the casing and the rotating body, the present invention relates to a method of sealing a flow of fluid flowing between a casing of a turbine and a rotating body rotated inside the casing A brush sealing apparatus for a turbine mounted on an inner circumference, comprising: a brush portion (12) disposed to surround an outer periphery of the rotating body, the brushes having a plurality of bristles each having the other end thereof contacting the outer periphery of the rotating body; A shock preventing part covering the front of the brush part and extending from the inner circumferential side of the casing toward the outer circumference of the rotating body such that the inner circumferential end portion is spaced apart from the outer circumference of the rotating body by a predetermined first interval; And a support plate which supports the rear portion of the brush portion and extends from the inner circumferential side of the casing to the outer periphery of the rotating body such that the inner circumferential end portion is spaced apart from the outer circumference of the rotor by a predetermined second interval, Lt; / RTI >

Description

[0001] Brush sealing apparatus for turbine [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a brush sealing apparatus for a turbine, and more particularly, to a brush sealing apparatus for a turbine that improves sealing performance and durability of a fluid flowing between a casing and a rotating body.

Generally, a turbine is a machine that converts the energy of a fluid such as water, gas or steam into rotational force. That is, a turbo type machine in which a rotating body formed with blades along the outer periphery is rotatably disposed inside a casing, and high-temperature steam or gas is blown to the blades to rotate at a high speed.

In this turbine, the fluid leaking between the rotating body and the fixed casing becomes a main cause of increasing the fuel cost by lowering the efficiency of the turbine, so that the importance of design technique of a seaing device for reducing fluid leakage is increasing, And it plays an important role in reducing vibration generation of the rotating body due to abnormal behavior of the fluid.

1 is a cross-sectional view showing a state where a conventional labyrinth-type sealing apparatus is mounted on a turbine, and Fig. 2 is a sectional view showing a conventional labyrinth-type sealing apparatus.

As shown in Figs. 1 and 2, the conventional labyrinth type sealing apparatus 5 is installed in the outer ring and the inner ring of the diaphragm 3 mounted on the casing. Here, the labyrinth type sealing device 5 is a non-contact type sealing device that reduces the leakage flow rate by using a throttling process of the fluid passing through the sharp tooth 5.

In detail, the fluid passes along the space between the tooth 6 and the rotating body which are arranged in order along the fluid flow direction, and the leakage flow rate of the fluid is reduced due to the pressure drop effect generated in the course of repeating throttling and expansion .

However, the conventional labyrinth type sealing apparatus has a problem that the amount of fluid leaking into the gap between the rotating body 1 and the teeth 6 is large. The leakage flow rate of the fluid can be reduced by narrowing the gap between the tooth 6 and the rotating body 1 but if the clearance between the tooth 6 and the rotating body 1 is narrow, The teeth 6 are brought into contact with the rotating body 1 in accordance with the vibration or thermal deformation of the rotating body 1 and are rapidly worn / deformed.

The fluid compressed in the narrow space between the tooth 6 and the rotating body 1 acts as a cause of causing the vibration of the rotating body 1 and the loss of the rotating force due to the vibration of the rotating body 1 occurs The efficiency of the turbine is deteriorated.

3 is a cross-sectional view of a conventional brush sealing apparatus.

3, the conventional brush sealing apparatus includes a brush portion 7 for sealing the gap between the rotating body 1 and the casing 3, a brush portion 7 for covering the front and rear sides of the brush portion 7, Plate (8, 9).

Here, the brush part 7 is provided in a densely packed form with a plurality of bristles, and can divide the high-pressure area and the low-pressure area to reduce the leakage of the fluid.

At this time, as each lower end portion of the bristles is in contact with the outer periphery of the rotating body 1 in a state where the upper end portion is fixed, the leakage flow of the fluid can be reduced as compared with the labyrinth type sealing apparatus, And the amount of rotational motion loss is reduced by supporting the outer periphery of the rotating body 1.

However, in the conventional brush sealing apparatus, the pressure of the fluid is concentrated on a portion exposed to the lower portion of the bristle plates 8 and 9, and a constant force is applied due to the frictional force with the rotating body 1, There is a problem in that the sealing performance against the outer circumference of the rotating body 1 during deformation sharply decreases.

Korean Patent Publication No. 10-2000-0016885

In order to solve the above problems, the present invention provides a brush sealing device for a turbine, which improves the durability of a product while improving the sealing performance of a fluid flowing between the casing and the rotating body.

According to an aspect of the present invention, there is provided a turbine brush sealing apparatus mounted on an inner circumference of a casing to seal a flow of fluid flowing between a casing of the turbine and a rotating body rotated inside the casing, A bristle including a plurality of bristles arranged to surround the outer periphery of the whole body, the brushes contacting the outer periphery of each of the other ends of the bristles; A shock preventing part covering the front of the brush part and extending from the inner circumferential side of the casing toward the outer circumference of the rotating body such that the inner circumferential end portion is spaced apart from the outer circumference of the rotating body by a predetermined first interval; And a support plate supporting the rear portion of the brush portion and extending from the inner circumferential side of the casing to the outer periphery of the rotating body such that the inner circumferential end portion is spaced apart from the outer circumference of the rotating body by a predetermined second interval, Wherein a plurality of guide grooves formed in a radial direction are formed on the rear surface of the support plate so that the fluid is guided toward the outer periphery of the brush unit, the guided fluid is throttled in the front portion of the support plate, Wherein the guide groove and the guide groove are opposed to each other such that the guide groove and the guide groove intersect with each other, and an expansion space, which is spaced apart from the brush part along the intersecting part, And the guide groove portion is formed in the inner periphery of the shock- It provides a turbine brush seal apparatus as that having characteristics such that the depth of the recessed toward the outer end portion from increasing.

Wherein the brush portion comprises a first brush portion having a first bristle having a diameter greater than 0.005 inches but less than 0.008 inches and a second brush portion having a second brush having a diameter of 0.004 inches or less but less than 0.005 inches, And the first brush portion and the second brush portion are disposed in a superposed manner forward and rearward to correspond to the flow direction of the fluid.

In the meantime, the present invention provides a brush sealing apparatus for a turbine mounted on an inner circumference of a casing for sealing a flow of a fluid flowing out between a casing of the turbine and a rotating body rotated inside the casing, A brush unit including a plurality of bristles each having an end on the other end of which is in contact with an outer circumference of the rotating body, the brush unit including a fixing plate to which one end of each of the bristles is fixed; A shock preventing part covering the front of the brush part and extending from the inner circumferential side of the casing toward the outer circumference of the rotating body such that the inner circumferential end portion is spaced apart from the outer circumference of the rotating body by a predetermined first interval; And a support plate which supports the rear portion of the brush portion and extends from the inner circumferential side of the casing to the outer periphery of the rotating body such that the inner circumferential end portion is spaced from the outer circumference of the rotating body by a predetermined second interval, And at the outer circumferential end of the support plate, a mounting portion formed with an insertion groove into which the fixing plate is inserted, the at least one of the insertion grooves supporting the outer circumferential surface of the fixing plate, And a supporting wing portion protruding at a predetermined width less than the front-rear width of the brush portion is provided on at least one of the rear surface of the shock-preventing portion and the front surface of the support plate. A brush sealing device for a turbine is provided.

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Through the above-mentioned solution, the brush sealing apparatus for a turbine according to the present invention provides the following effects.

First, since the front side first brush portion having high bending resistance and the rear side second brush portion having low bending resistance are deformed at different angles during rotation of the rotating body, the bristles passing through the boundary region between the respective brush portions Is narrowed by the adjacent bristles disposed at different angles, so that the sealing performance of the product can be improved.

Secondly, the shock preventing portion is disposed in close contact with the front of the brush portion to minimize the installation space, and the fluid is dispersed along the guide groove portion so as to pass through the entire brush portion, so that the pressure applied to each portion of the brush portion can be reduced. The fluid discharged to the rear side of the brush portion is depressurized by the throttling action of repeatedly expanding / contracting through the multi-stage interchangeable groove portion, so that the pressure of the finally discharged fluid is remarkably reduced and the sealing performance of the product can be improved.

Thirdly, since the guide groove portion is provided to increase the depth of depression toward the outer side of the brush portion, the fluid is expanded along the inner space where the fluid flowing along the guide groove portion expands and passes through the brush portion under the further reduced pressure, .

1 is a cross-sectional view showing a state where a conventional labyrinth type sealing device is mounted on a turbine.
2 is a cross-sectional view showing a conventional labyrinth type sealing apparatus.
3 is a cross-sectional view of a conventional brush seal device;
4 is a cross-sectional view showing a state in which a brush sealing device for a turbine according to an embodiment of the present invention is mounted so as to surround a rotating body.
5 is a cross-sectional view of a brush sealing apparatus for a turbine according to an embodiment of the present invention.
FIG. 6 is a rear view of a brush sealing apparatus for a turbine according to an embodiment of the present invention; FIG.
FIG. 7 is an exemplary view showing a deformation state of a brush part during rotation of a rotating body in a brush sealing device for a turbine according to an embodiment of the present invention; FIG.
FIG. 8 is an exemplary view showing an arrangement of a guide groove and an interchangeable groove portion with respect to a brush portion in a brush sealing apparatus for a turbine according to an embodiment of the present invention. FIG.
9 is a cross-sectional view of a brush sealing apparatus for a turbine according to another embodiment of the present invention.
10 is a rear view of a brush sealing apparatus for a turbine according to another embodiment of the present invention.
FIG. 11 is an exemplary view showing a deformation state of a brush part during rotation of a rotating body in a brush sealing device for a turbine according to another embodiment of the present invention. FIG.

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

FIG. 4 is a cross-sectional view showing a state in which a brush sealing device for a turbine according to an embodiment of the present invention is installed so as to surround a rotating body, FIG. 5 is a sectional view showing a brush sealing device for a turbine according to an embodiment of the present invention And FIG. 6 is a rear view of a turbine brush sealing apparatus according to an embodiment of the present invention. FIG. 7 is a perspective view illustrating a deformed state of the brush unit during rotation of a rotating body in a turbine brush sealing apparatus according to an embodiment of the present invention. And FIG. 8 is an exemplary view showing an arrangement of guide grooves and a transition groove portion with respect to a brush portion in a brush sealing apparatus for a turbine according to an embodiment of the present invention.

4 to 8, a brush sealing apparatus 100 for a turbine according to the present invention includes a turbine brush sealing apparatus 100 for rotating a turbine casing 20 and a rotating body 10 rotating in the casing 20, f of the casing 20 to seal the flow.

The outer periphery of the rotating body 10 is preferably understood to include the surface of the rotating body 10 and the end of the blade 27a coupled to the outer periphery of the rotating body. May be provided in a ring shape and may be installed in the circumferential direction between the outer periphery of the rotating body 10 and the fixed body such as the casing 20 or the like.

The sealing of the flow of the fluid f means that the high pressure area in front of the blade 27a of the rotating body 10 and the low pressure area in the rear of the blade 27a It is preferable to understand that the pressure is reduced to a low pressure region after the pressure of the high pressure region fluid is reduced.

Of course, the brush sealing device 100 may be installed between the casing 20 and the end of the blade 27a, between the casing 20 and the surface of the rotating body 10, It can be mounted at any position where sealing is required between the rotating bodies 10.

4, a fluid such as steam or gas introduced into the casing 20 passes through the partition 27 of the diaphragm fixed to the casing 20 and flows into the rotating body 10, Thereby rotating the blade 27a.

Then, the fluid f is discharged to the outside by repeating the step of rotating the next blade 27a according to the guidance of the partition 27 again. Through this process, the rotating body 10 supplies rotational force to the generator, and the generator converts rotational force into electrical energy.

Referring to FIG. 5, the turbine brush seal apparatus 100 includes a brush 130, an anti-shock unit 120, and a support plate 140.

Here, the brush seal apparatus 100 may be installed directly on the fixture such as the casing 20 or the partition 27, or may be installed on the fixture through a separate member such as the seal unit 110 In the following, as shown in the figure, the casing 20 is installed through the sealing part 110 as an example.

An engaging groove 21 is formed in the inner periphery of the fixed body such as the casing 20 along the circumferential direction and an engaging protrusion 111 inserted into the engaging groove 21 is formed on the outer periphery of the sealing portion 110. [ And the coupling protrusion 111 is slidably inserted through one end of the coupling groove 21 so that the sealing portion 110 can mount the casing 20.

At this time, an elastic member s is interposed between the coupling groove 21 and the coupling protrusion 111 so that the sealing portion 110 can be elastically supported to the rotary body 10 side.

In the inner circumference of the sealing part 110, a mounting groove 115 is formed to which the brush sealing device 100 is coupled. The mounting groove 115 is formed in the front and rear of the mounting groove 115 along the outer circumference of the rotating body 10 The labyrinth penetration portion 113 for blocking the flow of the flowing fluid can be projected in multiple stages.

Each of the labyrinth penetration parts 113 is annularly formed to extend from the inner periphery of the sealing part 110 toward the outer periphery of the rotary body 10 along the radial direction so as to surround the outer periphery of the rotary body 10, A gap through which the fluid (f) flows is formed between the end of the penetration part (113) and the outer periphery of the rotating body (10).

The fluid f flowing along the outer circumference of the rotating body 10 is compressed in a narrow space between the end of the labyrinth penetration portion 113 and the rotating body 10, The pressure can be lowered by repeating the expansion which is expanded in the wide space between the inner periphery of the portion 110 and the rotating body 10. [

In this way, the fluid f is lowered through the front labyrinth penetration portion 113 to reach the brush portion 130, and the fluid having passed through the brush portion 130 is re-introduced through the rear labyrinth through portion Since the pressure is strengthened, the leakage amount of the fluid can be remarkably reduced, and the sealing performance of the product can be improved.

The sealing part 110 is preferably made of an iron-based alloy or a copper-based alloy containing nickel, chromium, cobalt or the like which is stable against high temperature. The sealing part 110 and the penetration part 113, Is provided in a ring shape surrounding the outer periphery of the rotating body (10).

The sealing part 110 may be manufactured by a centrifugal casting process and may be manufactured in a garden type that is tightly coupled to the inner circumference of the casing 20. The outer circumference of the end of the rotating part 10, Can be precisely manufactured so as to correspond to predetermined design values.

The sealing portion 110 may be formed in a complete ring shape. However, the sealing portion 110 may be divided at a predetermined angle in order to improve the installation convenience with respect to the coupling groove 21, It is also possible to combine them in a shape.

The brush part 130 may be installed directly on the sealing part 110 or may be installed on the sealing part 110 through the shock preventing part 120 and the support plate 140 Hereinafter, the brush unit 130 is installed in the sealing unit 110 through the shock-preventing unit 120 and the support plate 140. FIG.

The brush 130 is disposed so as to surround the outer circumference of the rotating body 10, and each of the brushes 130 is provided with a plurality of bristles each having the other end in contact with the outer circumference of the rotating body 10.

Here, each of the bristles is preferably formed of a flexible material having elasticity and heat resistance. The bristles are made of a material having a strength lower than that of the rotary body 10 so as to be abraded without damaging the rotary body 10 during rubbing Respectively.

Each of the bristles is disposed at one end thereof on the lower surface of the sealing part 110 and the other end thereof is disposed in contact with the outer circumference of the rotary body 10 so that fluid f) can be sealed.

In this case, when the shock absorber 120 and the support plate 140 are integrally connected to each other, the shock absorber 120 and the support plate 140, Shaped fixing plate 131 for the purpose of improving the convenience of replacement, and the shock-preventing portion 120 (not shown) may be fixed to the fixing plate 131 through the fixing plate 131, And the support plate 140. [0035]

In detail, the brush part 130 is provided in a densely packed form with a plurality of bristles, and the fluid f may pass through a narrow gap between the bristles to reduce pressure and speed.

The shock preventing part 120 and the support plate 140 are disposed on the front and rear sides of the brush part 130 so that their respective ends are spaced apart from the outer circumference of the rotary body 10, The fluid f may flow through the gap between the end of the shock preventing portion 120 and the support plate 140 and the rotating body 10. [

5 to 6, the shock preventing part 120 covers the front of the brush part 130, and has an inner circumferential end spaced apart from the outer circumference of the rotating body 10 by a predetermined first interval So as to extend from the inner circumference side of the casing (20) toward the outer circumference of the rotating body (10).

It should be understood that the inner circumferential side of the casing 20 means the inner circumference of the sealing portion 110 when the shock preventing portion 120 is installed in the casing 20 through the sealing portion 110 Do.

The outer circumferential end means an end adjacent to the inner circumference of the sealing portion 110. The inner circumferential end portion of the shock preventing portion 120 means an end adjacent to the outer circumference of the rotating body 10, It is desirable to understand what it means.

That is, the shock preventing part 120 is provided in an annular shape extending from the inner periphery of the sealing part 110 toward the outer periphery of the rotating body 10, and the inner circumferential end of the shock preventing part 120 and the rotating body 10 are spaced apart from each other by a distance corresponding to the first gap to form a gap through which the fluid f flows.

At this time, it is preferable that the rear portion of the shock preventing portion 120 is disposed in contact with the front portion of the brush 130.

A plurality of guide grooves 126 are radially formed on the rear surface of the shock preventing part 120 so that the fluid f is guided toward the outer periphery of the brush part 130 along the radial direction. Here, the outer circumference of the brush part 130 is understood to mean a part corresponding to one end side of each bristle fixed,

At this time, the guide groove 126 is formed to be recessed from the inner peripheral end of the rear portion of the shock absorber 120 toward the outer peripheral end, and an opening through which the fluid f flows into the inner peripheral end of the shock absorber 120 is formed do.

Specifically, the shock preventing portion 120 is disposed on the front side of the brush portion 130, which is the fluid inflow direction side, and the fluid f is in contact with the front surface of the shock preventing portion 120 And then flows toward the brush part 130 along the gap formed between the inner circumferential end of the shock preventing part 120 and the outer circumference of the rotating body 10. [

The direct impact between the high pressure fluid f flowing at high speed and the brush part 130 can be reduced and the speed / pressure of the fluid f itself and the high speed flow of the foreign matter in the fluid f The damage of the brush 130 due to abrasion is minimized and the durability of the product can be improved.

A part of the fluid f flowing between the end of the shock preventing part 120 and the outer periphery of the rotating body 10 passes through the inner peripheral side of the brush part 130 and flows into the low pressure area, And flows along the guide groove 126 toward the outer peripheral end side of the rear portion of the shock preventing portion 120 and passes through the brush portion 130.

As described above, the shock preventing part 120 is closely attached to the brush part 130 to minimize the installation space, and the fluid can be dispersed and passed through the brush part 130 through the guide groove part 126.

The compressed fluid reaching the space between the end of the shock preventing part 120 and the outer circumference of the rotating body 10 is guided in the space between the front end of the guide groove 126 and the front end of the shock preventing part 120 and the brush part 130 And is dispersed and passes through the whole of the brush part 130, the amount of fluid leakage can be remarkably reduced due to the pressure reduction of the fluid passing through each part of the brush part 130 .

Further, since the fluid f, which has conventionally been concentrated on a portion adjacent to the outer periphery of the rotating body 10, is dispersed through the guiding groove portion 126, the amount of vibration generated in the rotating body 10 due to the concentrated pressure is reduced, And the efficiency of the turbine can be improved.

At this time, it is preferable that the guide groove 126 is formed to increase the depth of depression from the inner circumferential end to the outer circumferential end of the shock absorber 120. That is, the guide groove 126 is formed so as to be deeply recessed away from the outer circumference of the rotating body 10 to have a minimum diameter at the inner circumferential end of the shock preventing part 120, And it is preferable to have a maximum diameter at the outer peripheral end.

Accordingly, the fluid f flows into the guide groove 126, is guided to the outer side of the brush 130, expands through the widened internal space, and is depressurized. Accordingly, the brush 130 And the leakage amount of the fluid is reduced because the fluid passes through the brush part 130 under an additional reduced pressure, so that the sealing performance of the product can be improved.

6 to 7, the brush 130 includes a first brush 130a having a first bristle diameter exceeding 0.005 inches but a diameter of 0.008 inches or less, and a second brush 130b having a diameter of 0.005 And a second brush portion 130b having a second bristle having a diameter of not greater than 2 inches.

That is, the first brush part 130a includes a plurality of first bristles arranged in the circumferential direction of the rotating body 10, and the second brush part 130b has a diameter smaller than that of the first bristle 130b. And a plurality of bristles are arranged in the circumferential direction of the rotating body 10 in a plurality.

At this time, when the first bristle has a diameter exceeding 0.008 inches, there is a fear that the outer circumference of the rotating body 10 is supported by an excessive pressure to increase the amount of generated vibration, and when the second bristle is less than 0.004 inch In the case of having a diameter, there is a fear that the sealing property is lowered due to excessive elastic deformation.

Here, the first bristles and the second bristles are made of the same material, and the first brush portion 130a formed by the first bristle is formed of a second brush portion formed by a relatively thin second bristle 130b. ≪ / RTI >

The first brush part 130a and the second brush part 130b are disposed in a superposed manner forward and rearward to correspond to the flow direction of the fluid. In this case, the brushes 130a and 130b are preferably formed in a ring shape to completely surround the brush body 130 in the circumferential direction of the rotating body 10.

Here, it is preferable that the first brush part 130a formed by the thick first bristle and having high rigidity and high bending resistance is disposed on the front side facing the flow of the fluid, and it is formed by the thin second bristle, And the second brush portion 130b having high hermeticity is disposed behind the first brush portion 130a.

Accordingly, since the fluid is firstly decelerated by the first brush portion 130a having a high bending resistance and flows to the second brush portion 130b, the deformation amount of the second brush portion 130b having high hermeticity and low bending resistance is reduced So that the hermeticity of the brush part 130 can be improved.

In addition, since the foreign matter flowing together with the fluid is filtered by the high-rigidity first brush portion 130a, the damage of the second brush portion 130b having a relatively low rigidity is reduced, so that the durability of the brush portion 130 Can be improved.

The first brush 130a may have a longitudinal width of about 20 to about 50% with respect to a longitudinal width of the entire brush 130. The second brush 130b may include an entire brush portion 130a, It is preferable to have a longitudinal width of 50 to 80% based on the front-to-rear width of the front plate 130.

In this case, when the first brush part 130a is less than 20% and the second brush part 130b is more than 80%, there is a fear that the actual supporting force is lowered. When the first brush part 130a is 50 % And the second brush part 130b is less than 50%, the airtightness may be excessively lowered.

When the brush portions 130a and 130b are deformed by the friction of the rotation of the rotating body 10, the first brush portion 130a having a high bending resistance has a small amount of circumferential deformation and a low bending resistance, The portion 130b has a greater amount of circumferential deformation than the first brush portion 130a. That is, when the rotating body 10 rotates, the first brush portion 130a and the second brush portion 130b are deformed at different angles.

Accordingly, the narrow gap between the bristles through which the fluid passes in the boundary region between the brush portions 130a, 130b can be shielded and narrowed by the adjacent bristles disposed at different angles, so that the sealing performance of the product can be improved .

The high rigidity and durability of the first brush portion 130a and the hermeticity of the second brush portion 130b form a synergy through the overlap of the first brush portion 130a and the second brush portion 130b in the forward and backward directions The gap between the bristles is narrowed by the different amount of deformation of the first brush portion 130a and the second brush portion 130b, so that the sealing performance of the product can be remarkably improved.

The support plate 140 supports the rear portion of the brush 130 and has an inner circumferential end extending from the inner circumferential side of the casing 20 so as to be spaced apart from the outer circumference of the rotator 10 by a predetermined second interval And extends toward the outer periphery of the rotating body (10).

Here, when the support plate 140 is installed in the casing 20 through the sealing portion 110, it is preferable that the inner circumference side of the casing 20 means the inner circumference of the sealing portion 110 .

The term "inner circumferential end" of the support plate 140 is understood to mean an end adjacent to the outer circumference of the rotating body 10, and the term "circumferential end" means an end adjacent to the inner circumference of the sealing portion 110 It is desirable to understand that

That is, the support plate 140 is annularly extended from the inner periphery of the sealing portion 110 toward the outer periphery of the rotating body 10, and the inner periphery of the support plate 140, And a gap through which the fluid f flows is formed in correspondence with the second gap.

At this time, the second gap is less than the first gap such that the gap between the support plate 140 and the rotator 10 is narrower than the gap between the shock preventing portion 120 and the rotator 10 Preferably set.

The front surface of the support plate 140 is disposed so as to be in contact with the rear surface of the brush 130 and supports the rear of the brush 130 to reduce the warpage of each brush due to the pressure of the fluid f Can be minimized.

As a result, the end portions of the bristles are held in close contact with the rotating body 10, so that the leakage amount of the fluid passing through the brush portion 130 is reduced, and the sealing performance of the product can be improved.

In addition, an arcuate diagonal grooved groove portion 146, which is circumferentially recessed to flow toward the outer periphery of the rotating body 10, is formed in the front portion of the support plate 140 in a radial direction Are provided in multiple stages.

The fluid f passing between the shock preventing portion 120 and the rotating body 10 is dispersed to each portion from the inner circumference to the outer circumference side of the brush portion 130 through the guiding groove portion 126 And passes through the brush part 130.

At this time, the fluid f passing through the outer side of the brush 130 flows to the outer circumference side of the rotating body 10 along the front surface of the support plate 140, Pressure area behind the brush part 130 along the gap between the brush part 130 and the brush part 130. [

The fluid f guided to the outer periphery of the brush 130 and discharged to the gap of the support plate 140 passes through the multistage shroud grooves 146, The pressure is lowered through the throttling action which expands in space and contracts in a narrow space between the throat grooves 146. [

Accordingly, the pressure of the fluid (f) that has passed through the brush part (130) is significantly reduced, and the sealing performance of the product can be improved.

5 to 8, the guide groove 126 and the diaphragm groove 146 may be disposed opposite to each other, and may include an expansion space k (not shown) spaced apart from the brush 130 along the intersection, ) Are repeatedly formed in a lattice shape.

More specifically, the radial guide groove 126 formed in the shock preventing portion 120 and the arc-shaped narrow groove portion 146 of the support plate 140 are disposed opposite to each other with a cross shape like a spider web.

At this time, a portion intersecting with the guide groove 126 and the diaphragm groove 146 forms a wide expansion space k having grooves in front of and behind the brush 130, and only the guide groove 126 The formed portion forms a first space m having a middle width spaced apart from the front of the brush portion 130. The portion formed only with the throttled groove portion 146 is formed by a half width portion of the rear portion of the brush portion 130, And the third space c having a narrow width in which the front and rear sides of the brush portion 130 are closely contacted is formed at a portion where the guide groove portion 126 and the diaphragm groove portion 146 do not exist .

The expansion space k, the first space m, the second space t and the third space c are connected to the brush portion 130 ) In a lattice shape.

That is, a space having various front and rear widths is formed between the shock preventing part 120 and the support plate 140, and the fluid f flowing into the brush part 130 is expanded And a different pressure at each internal portion due to contraction.

Accordingly, a complicated flow of fluid f can be generated inside the brush 130, and a complicated flow of fluid f can reduce the amount of leakage of the following fluid f.

The shock preventing part 120 and the support plate 140 are manufactured by a centrifugal casting and are integrally formed with a ring shape and then cut and divided at a predetermined angle so that the shape precision and productivity of the parts can be improved have.

At this time, the shock preventing part 120 and the support plate 130 may be integrally connected to each other at their upper ends, or they may be separated from each other as shown in FIG. .

The outer circumferential end portions of the shock preventing portion 120 and the support plate 130 are coupled to each other by means of fastening means b and n and formed with insertion holes 121 and 141 in which the fastening plate 131 is inserted, (123, 143).

Here, the outer circumferential end portions of the shock preventing portion 120 and the support plate 130 are understood to mean a portion adjacent to the inner circumference of the sealing portion 110 indicated at the upper side in the drawing, A portion adjacent to the outer periphery of the rotating body 10 will be referred to as a lower portion and a portion adjacent to the inner periphery of the casing 20 will be referred to as an upper portion.

The mounting portion 123 of the shock preventing portion 120 is inserted into the mounting recess 115 of the sealing portion 110 and is inserted into the mounting recess 115 in the forward direction. .

Insertion grooves 121 and 141 are formed in the lower portion of the rear portion of the mounting portion 123 of the shock preventing portion 120 and the front lower portion of the mounting portion 143 of the support plate 130 along mutually opposite portions.

At this time, a bolt hole is formed in the upper portion of the mounting portions 123 and 143, and the shock preventing portion 120 and the support plate 140 can be coupled through fastening means b and n such as bolts / nuts. When the front and rear ends of the fixing plate 131 are inserted into the respective insertion grooves 121 and 141 when the two members are engaged with each other, the brush 130 can be coupled to the shock preventing part 120 and the support plate 140 have.

The space between the insertion grooves 121 and 141 is preferably larger than the width from the front end to the rear end of the fixing plate 131. The shock preventing part 120 may be formed through the fastening means b and n, And the support plate 140, the density of the brush part 130 can be adjusted.

Preferably, at least one of the insertion grooves 121 and 141 supports the outer circumferential surface of the fixing plate 131, and the supporting protrusions 122 are inserted into the other insertion grooves to engage with each other.

In other words, one of the two insertion grooves 121 and 141 is formed so as to correspond to the thickness of the fixing plate 131 by projecting the supporting protrusion 122, and the other is formed by the thickness of the supporting protrusion 122 and the fixing plate 131 Are formed so as to correspond to the sum.

The support protrusions 122 formed in the one insertion groove 121 are inserted into the other insertion groove 141 and the shock preventing portion 120 and the support plate 140 are engaged with each other at a portion where the shock protector 120 and the support plate 140 are in contact with each other. And it is possible to prevent the fluid f flowing into the brush 130 from leaking to the upper portion of the fixing plate 131. [

FIG. 9 is a cross-sectional view of a turbine brush sealing apparatus according to another embodiment of the present invention, FIG. 10 is a rear view of a brush sealing apparatus for a turbine according to another embodiment of the present invention, FIG. 5 is a view showing a deformation state of a brush part during rotation of a rotating body in a brush sealing device for a turbine according to another embodiment of the present invention.

In the present embodiment, the basic configuration except for that the support vane portion is provided on any one of the shock preventing portion and the support plate is the same as that of the above-described embodiment, so a detailed description of the same configuration will be omitted, Number.

9 to 11, at least one of the rear surface of the shock-preventing portion 120 and the front surface of the support plate 140 is provided with a support blade (not shown) It is preferable that a portion 127 is provided.

The support wing portion 127 is formed on one side of the rear surface of the shock preventing portion 120 and the front surface of the support plate 140 so as to be inserted into the brush portion 130, 120, or may be formed to extend forward from the front surface of the support plate 140.

In this case, the support vane 127 is preferably formed on the support plate 140 in consideration of the flow of the fluid. However, in consideration of the diaphragm groove 146 formed in the support plate 140, And between the guide grooves 126 of the guide groove 120.

In detail, the support vane 127 is formed in the radial direction of the rotation shaft 10 along the lower portion of the insertion groove 121 of the shock prevention part 120, and is formed up to the lower end of the shock prevention part 120 And may be formed along a portion spaced from the lower end of the insertion groove 121 and spaced apart from the lower end of the shock preventing portion 120.

Preferably, the support vanes 127 are formed to have a width of 30 to 60% with respect to the entire width of the brush 130 in the front-rear direction.

At least one support wing 127 may be provided on the rear portion of the shock absorber 120. When the plurality of support wings 127 are formed, the support wings 127 may be uniformly arranged at angles of 90 degrees and angles of 120 degrees Spaced apart from one another by an interval.

Meanwhile, referring to FIG. 11, the support wing portion 127 may support the bristles corresponding to the inserted portion in the circumferential direction. That is, when deformation occurs in the bristle due to friction during rotation of the rotating body 10, the amount of deformation of the portion of the bristle supported by the supporting wings 127 by inserting the supporting wings 127 is reduced .

That is, the front portion of the brush 130 supported by the support vanes 127 and the rear portion of the brush 130 that are not supported by the support vanes 127 when the rotor 10 rotates are at different angles It can be deformed.

Thus, the sealing performance of the brush portion 130 can be improved since the narrow gap between the bristles through which the fluid passes is narrowed and narrowed by the adjacent bristles at the intersections between the bristles deformed at different angles.

As described above, the present invention is not limited to the above-described embodiments, and variations and modifications may be made by those skilled in the art without departing from the scope of the present invention. And such modifications are within the scope of the present invention.

1,10: rotating body 2,20: casing
3: Diaphragm 5: Labyrinth type sealing device
6: tooth 7: brush part
8,9: Bristol plate 21: Coupling groove
27: partition 27a: blade
100: Brush sealing device 110:
111: engaging projection 113: labyrinth tweezer
115: mounting groove 120: shock prevention part
121, 141: insertion grooves 123, 143:
126: guide groove part 127: support blade part
130: Brush part 131: Fixing plate
140: support plate 146:

Claims (5)

A turbine brush sealing apparatus mounted on an inner circumference of a casing for sealing a flow of fluid flowing between a casing of the turbine and a rotating body rotated inside the casing,
A brush portion disposed to surround an outer periphery of the rotating body, the brushes having a plurality of bristles each having the other end contacting the outer periphery of the rotating body;
A shock preventing part covering the front of the brush part and extending from the inner circumferential side of the casing toward the outer circumference of the rotating body such that the inner circumferential end portion is spaced apart from the outer circumference of the rotating body by a predetermined first interval; And
And a support plate extending from the inner circumferential side of the casing to the outer circumference of the rotating body so as to support the rear portion of the brush portion, the inner circumferential end portion being spaced apart from the outer circumference of the rotating body by a predetermined second interval,
Wherein a plurality of guide grooves formed in a radial direction are formed on the rear surface of the shock preventing portion so that the fluid is guided toward the outer periphery of the brush portion, wherein the guide fluid is throttled in the front portion of the support plate, An arc-shaped interchangeable groove formed in a circumferential direction so as to flow toward the outer periphery is provided in multiple stages along the radial direction,
Wherein the guiding groove portion and the wedge groove portion are arranged so as to be opposed to each other so that an expansion space spaced apart from the brush portion along the intersecting portion is repeatedly formed in a lattice shape and the guiding groove portion is guided from the inner circumferential end portion to the outer circumferential end portion side Wherein the depth of the recess is increased. The method according to claim 1,
The brush part
A first brush portion having a first bristle diameter of greater than 0.005 inches but less than or equal to 0.008 inches, and a second brush portion having a second bristle diameter of at least 0.004 inches but less than or equal to 0.005 inches,
Wherein the first brush portion and the second brush portion are disposed so as to be superimposed forward and rearward to correspond to a flow direction of the fluid. delete delete A turbine brush sealing apparatus mounted on an inner circumference of a casing for sealing a flow of fluid flowing between a casing of the turbine and a rotating body rotated inside the casing,
A bristle including a plurality of bristles each of which is disposed on the outer periphery of the rotating body so as to surround an outer periphery of the rotating body, the brushes having one end fixed to the bristles;
A shock preventing part covering the front of the brush part and extending from the inner circumferential side of the casing toward the outer circumference of the rotating body such that the inner circumferential end portion is spaced apart from the outer circumference of the rotating body by a predetermined first interval; And
And a support plate extending from the inner circumferential side of the casing to the outer circumference of the rotating body so as to support the rear portion of the brush portion, the inner circumferential end portion being spaced apart from the outer circumference of the rotating body by a predetermined second interval,
The shock-preventing portion and the outer peripheral end portion of the support plate are provided with a mounting portion formed with an insertion groove into which the fixing plate is inserted,
Wherein at least one of the insertion grooves is provided with a support protrusion for supporting the outer circumferential surface of the fixing plate so as to be inserted into and engaged with another insertion groove,
Wherein at least one of the rear surface of the shock-preventing portion and the front surface of the support plate has a support wing portion protruding at a predetermined width less than the front-rear width of the brush portion.

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