KR20150141069A - Brush seal assembly - Google Patents

Abstract

A brush seal assembly is disclosed. According to one embodiment of the present invention, the brush seal assembly comprises: a packing body which has an insertion groove positioned between a rotor and a fixated body and formed inward in a circumferential direction, and has an insertion hole having openings disposed toward the insertion groove at different positions and in different directions; a brush seal unit which has a brush extended toward the rotor when brush is disposed in the insertion groove and has a support member supporting the brush; a thermal expansion member closely attached to a side surface of the support member and thermally expanded in the circumferential direction of the packing body; and a fixing member inserted into a first and a second insertion hole from the outside of the packing body to maintain a fixed state of the brush seal unit in the radial and the circumferential directions of the packing body.

Description

[0001] Brush seal assembly [

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a brush seal, and more particularly, to a brush seal assembly used to seal a gap between a fixture of a turbine and a rotating body.

Generally, a turbine is a power generating device that converts thermal energy of a fluid such as gas or steam into rotational force as mechanical energy. The turbine includes a rotor including a plurality of buckets for axial rotation by a fluid, And a casing which surrounds the rotor and includes a plurality of diaphragms.

Here, the gas turbine includes a compressor, a combustor, and a turbine. External air is sucked and compressed by rotation of the compressor, and then sent to a combustor. Combustion is performed by mixing the compressed air and fuel in the combustor. The high-temperature and high-pressure gas generated from the combustor passes through the turbine and rotates the rotor of the turbine to drive the generator.

In the case of a steam turbine, a high-pressure turbine, a medium-pressure turbine, and a low-pressure turbine are connected in series or parallel to rotate the rotor. In the case of a series structure, a high-pressure turbine, a medium-pressure turbine, and a low-

Each of the turbines in the steam turbine has a fixed blade and a rotor blade around a rotor inside the casing, and the steam can pass through the fixed blade and the rotor blade to rotate the rotor to drive the generator.

At this time, since the gas turbine and the steam turbine have a structure in which the rotor (rotor) relatively rotates with respect to the fixed body (fixed wing), leakage of high temperature and high pressure fluid occurs between the fixed body and the rotating body, Is a cause of energy efficiency degradation due to power loss and efforts are continuously being made to reduce the leakage of fluid generated in the gap between the rotating body and the fixed body.

In order to minimize the leakage of fluid, the gap between the fixed body and the rotating body should be minimized, but there are various limitations in narrowing the gap.

For example, when the clearance is too narrow, the rotating body and the stationary body interfere with each other when the rotating body rotates, causing vibration due to rubbing, which causes serious damage to the turbine.

On the other hand, the steam turbine expands or shrinks from several millimeters to several tens mm depending on the position during operation and start-stop because the high-temperature steam flowing from the boiler exerts heat on the rotor and the fixture. At this time, the characteristics of the rotating body and the fixed body differ not only not only differently, but also the direction of expansion depending on the structure of the turbine, so that the rotating body and the fixed body may interfere with each other during operation and rubbing may occur.

Conventionally, a labyrinth seal has been used for sealing. In recent years, a brush seal having a brush coupled to a labyrinth seal is applied to eliminate the gap between the fixture and the rotating body, A technique of sealing them in the form of contacting each other has been developed.

US6790001B2 (registered on September 14, 2004)

Embodiments of the present invention are intended to stabilize the brush seal assembly in different positions and orientations to improve the efficiency of the turbine provided with the brush seal assembly and to constantly move the fluid through the brush seal at all times.

Embodiments of the present invention are intended to maintain the amount of fluid movement constant regardless of the pressure fluctuation applied to the brush chamber.

According to an aspect of the present invention, there is provided a packing body comprising: an insertion groove formed between a rotating body and a fixture and formed in a circumferentially inner side; and an insertion hole opened at different positions and directions toward the insertion groove; A brush chamber extending from the insertion groove to the rotation body, and a support member for supporting the brush; A thermal expansion member in close contact with a side surface of the support member and performing thermal expansion in a circumferential direction of the packing body; And And a fixing member inserted into the first and second insertion holes from the outside of the packing body to maintain the fixed state of the brush seal part in the radial direction and the circumferential direction of the packing body.

The insertion hole has a first insertion hole opened toward the insertion groove in the radial direction of the packing body; And a second insertion hole opened from the outer surface of the packing body toward the insertion groove.

And the second insertion holes are located between the first insertion holes spaced apart at regular intervals.

And the second insertion hole is opened at an intermediate position between the first insertion holes.

And the second insertion hole is opened in the middle with respect to the longitudinal direction of the packing body.

And the second insertion hole is open at either or both of the left and right sides with respect to the front surface of the packing body.

And the first insertion hole is opened so as to be orthogonal to the packing body.

And the first insertion hole is formed with a thread in the inner circumferential direction.

And the first and second insertion holes are formed with threads in the inner circumferential direction.

The fixing member includes: a first fixing member inserted into the first insertion hole; And a second fixing member inserted into the second insertion hole.

Wherein the first fixing member has a body in surface contact with the upper surface of the brush seal portion; And a head formed on an upper surface of the body, wherein the head is integrally inserted into the first insertion hole.

The body is formed with a threaded portion in a lower part of a lower part thereof and is made of a thermal expansion material, and is thermally expanded in a radial direction of the packing body.

The brush seal assembly includes a third insertion hole formed on an upper surface of the brush seal portion such that a lower end of the first fixing member is partially inserted.

Wherein the first fixing member is a bolt, and the second fixing member is a pin.

The first and second fixing members may be bolts.

The fixing member includes a tool insertion groove formed on an upper surface thereof for insertion of the tool.

The support member includes a first support plate having a guide groove formed on one side of the brush and having a guide groove for guiding the flow of the fluid toward the lower side of the brush, And a second support plate which is in close contact with the brush in a state facing the first support plate and is formed at a position facing the thermal expansion member.

And the thermally expanding members are independently arranged facing each other with respect to the insertion hole.

According to another aspect of the present invention, there is provided a brush seal assembly comprising: an insertion groove formed on an inner side in a circumferential direction and positioned between a rotating body and a fixed body; a first insertion hole radially formed on the outer peripheral surface, A packing body located at a different position from the insertion hole and including a second insertion hole opened toward the insertion groove; A brush chamber extending from the insertion groove to the rotation body, and a support member for supporting the brush; A thermal expansion member in close contact with a side surface of the support member and performing thermal expansion in a circumferential direction of the packing body; And a fixing member inserted into the first and second insertion holes from the outside of the packing body, respectively, for maintaining the fixed state of the brush seal part in the radial direction and the circumferential direction of the packing body.

And the second insertion hole is opened toward the thermal expansion member.

And the second insertion holes are located between the first insertion holes spaced apart at regular intervals.

And the thermally expanding members are independently disposed facing each other with respect to the second insertion hole.

The fixing member includes: a first fixing member inserted into the first insertion hole; And a second fixing member inserted into the second insertion hole.

The first fixing member is pressed inward with respect to the radial direction of the packing body in a state in which the lower end is in close contact with the upper surface of the brush seal portion, And the second fixing member is located at the center of the thermal expansion member to prevent the packing body from moving in the circumferential direction.

Wherein the first fixing member has a body in surface contact with the upper surface of the brush seal portion; And a head formed on an upper surface of the body, wherein the head is integrally inserted into the first insertion hole.

The body is formed with a thread in a part of the lower part and is made of a thermal expansion material, and is thermally expanded in a radial direction of the packing body.

Embodiments of the present invention improve the fixation performance of the brush seal part by fixing the brush seal assembly in different positions and directions and maintain the gaps between the rotator and the rotation constantly so that the generation of heat and abrasion in the brush is minimized, / RTI >

In the embodiments of the present invention, since a certain amount of fluid is passed through the gap between the rotating body and the brush room, the efficiency of the turbine can be improved, the power generation can be increased, the durability of the brush chamber assembly is improved, And the cost incurred due to replacement and repair is reduced.

1 is a cross-sectional view illustrating a state in which a brush seal assembly according to an embodiment of the present invention is positioned between a rotating body and a fixed body.
2 is an exploded perspective view of a brush seal assembly according to an embodiment of the present invention.
FIG. 3 is an assembled cross-sectional view of a brush seal assembly in accordance with an embodiment of the present invention. FIG.
Figure 4 is an assembled cross-sectional view of a brush seal assembly in accordance with another embodiment of the present invention.
5 is a perspective view illustrating a state in which a fixing member is coupled to a brush seal part according to an embodiment of the present invention.
FIG. 6 is a plan view showing a state where a fixing member is fixed to a brush chamber according to an embodiment of the present invention. FIG.
7 is a longitudinal cross-sectional view of a brush seal assembly in accordance with an embodiment of the present invention.
8 is a longitudinal sectional view of a brush seal assembly according to another embodiment of the present invention.
9 is an exploded perspective view of a brush seal assembly according to another embodiment of the present invention.
10 is a perspective view illustrating a state in which a fixing member is positioned on a brush seal assembly according to another embodiment of the present invention.
FIG. 11 is a plan view of a fixing member fixed to a brush chamber according to another embodiment of the present invention. FIG.
12 is a longitudinal sectional view of a brush seal assembly according to another embodiment of the present invention.
13 is a longitudinal sectional view of a fixing member according to another embodiment of the present invention installed in a brush seal part.
14 is a longitudinal sectional view of a brush seal assembly according to another embodiment of the present invention.
15 to 16 are operational states of a brush seal assembly according to another embodiment of the present invention.

The construction of a brush seal assembly according to an embodiment of the present invention will be described with reference to the drawings. For reference, FIG. 1 shows an example in which a labyrinth seal 1 and a brush seal 2 are applied to a gap between a fixed body and a rotating body of a steam turbine.

1 to 3, the holding body includes a casing 3 and a fixed blade 4, and the rotating body includes a rotor 5 and a rotor blade 6. The fixed blade 4 is engaged with the casing 3 and disposed at a position adjacent to the rotor blade 6 and the rotor blade 6 is axially rotated integrally with the rotor 5 in a state adjacent to the fixed blade 4.

Sealing is required for the gap between the fixed blade 4 and the rotor blade 6 and the gap between the fixed blade 4 and the rotor 5 and the brush chamber assembly 1 is used for this purpose.

The brush seal assembly 1 includes a packing body 100, a brush seal part 200, a thermal expansion member 300 and a fixing member 400, A stable airtightness is maintained through the brush seal part 200. [

At this time, the entirety of the brush seal part 200 is kept fixed in the radial direction and the circumferential direction of the packing body 100 by the heat conduction transmitted to the brush seal part 200 through the rotor 5, And the airtightness is stably maintained by being fixed by the fixing member 400 toward the inside or outside in the radial direction.

The packing body 100 is positioned between the rotor 5 and the fixed body and has the insertion groove 110 formed thereon while looking at the rotor. The packing body 100 includes a plurality of individual unit bodies, ) In the outer circumferential direction. That is, a plurality of packing bodies 100 having a predetermined length are provided on the outer side of the rotor 5 in a state in which they are in close contact with each other.

The packing body 100 includes an insertion hole 120 which is radially opened on the outer circumferential surface at different positions and directions toward the insertion groove 110. The insertion hole 120 includes a first insertion hole 122 opened in the radial direction of the packing body 100 and a second insertion hole 124 opened toward the insertion groove 110 on the side of the outer peripheral surface.

The first insertion hole 122 and the second insertion hole 124 are opened in a position and a direction different from each other. The first insertion hole 122 is opened at regular intervals on the upper surface with reference to the brush seal part 200 And is opened toward the radial direction of the packing body (100). The second insertion hole 124 is positioned on the side surface of the brush seal portion 200 with respect to the brush seal portion 200. The direction of the second insertion hole 124 is orthogonal to the first insertion hole 122 so as to extend in the circumferential direction of the brush seal portion 200 Is opened.

A brush member 200 to be described later is inserted into the insertion groove 110 and a fixing member 400 is inserted into the first and second insertion holes 122 and 124 to fix the brush seal unit 200.

Since the brush seal part 200 is kept pressed by the fixing member 400 in the radial direction and the circumferential direction of the packing body 100 by the thermal expansion member 300, The fluid is always passed through a predetermined amount to prevent unnecessary leakage, thereby stabilizing the efficiency of the object on which the brush seal assembly 1 is installed.

Accordingly, even when friction is generated directly or indirectly with the rotor 5 for a long period of time, the sealing loss due to abrasion and deformation is minimized and a constant gap between the brush 210 and the rotor 5 is maintained .

In particular, if the clearance between the rotor 5 and the brush 210 is excessively spaced from each other, a high-pressure fluid may leak, which may cause an overall power loss of the rotor 5.

The gap between the rotor 5 and the brush 210 is kept constant because interference occurs between the rotor 5 and the fixture when the rotor 5 and the brush 210 are in close contact with each other It is important.

The brush seal unit 200 includes a brush 210 extending toward the rotor 5 in a state of being inserted into the insertion groove 110 and a support member 220 for supporting the brush 210, A thermal expansion member 300 which is in close contact with a side surface of the member 220 and thermally expands in a circumferential direction of the packing body is positioned on a side surface of the brush seal portion 200.

The fixing member 400 is inserted into the first and second insertion holes 122 and 124 from the outer side of the packing body 100 so that the fixing state of the brush seal part 200 in the radial direction and the circumferential direction of the packing body 100 .

The first insertion hole 122 is opened at the center of the upper surface of the brush seal part 200 and is spaced apart at a predetermined distance. When the fixing member 400 is inserted in a state orthogonal to the packing body 100, And the fixing force applied by the fixing member 400 is stably maintained regardless of the position.

The first insertion hole 122 is formed with a thread on the inner circumferential surface thereof and a fixing member 400 to be described later is screwed to stably maintain the fixation with respect to the brush seal part 200 via the packing body 100.

The second insertion hole 124 is opened toward the inside of the packing body 100 at a side position other than the upper side with respect to the outer circumferential surface of the packing body 100. The first insertion hole 122, Or at an intermediate position between the first insertion holes 122 spaced apart.

4, the brush seal assembly 1 includes a third insertion hole 202 formed in the upper surface of the brush seal part 200 such that the lower end of the first fixing member 410 is partially inserted. When the first fixing member 410 is screwed into the third insertion hole 202, the brush seal portion 200 is stably held in place by the first fixing member 410, And the brush 210 are kept constant at all times, and the state of being in close contact with the insertion groove 110 is kept constant to prevent fluid leakage. Further, since the upper side of the brush seal part 200 is fixed by the first fixing member 410, the fixed state is stably maintained even when the pressing force is applied from the lower side to the upper side of the brush seal part 200.

5, when the distance between the first insertion holes 122 is assumed to be L, the two insertion holes 120 are opened at a position of 1/2 * L to fix the brush seal portion 200 to the .

The second insertion hole 124 may be open to one or both of the left and right sides of the front surface of the packing body 100. In this embodiment, the second insertion hole 124 is limited to the left side of the packing body 100 Explain that one position is variable.

The first and second insertion holes 122 and 124 may be threaded in the inner circumferential direction or may be formed in the first insertion hole 122 only and the second insertion hole 124 may be formed in a threadless shape.

The thermal expansion member 300 is extended in a state of being closely attached along the longitudinal direction of the second support plate 224 and is thermally expanded in the circumferential direction of the packing body 100 by transferring the heat transferred from the high temperature fluid

5 to 7, the fixing member 400 is fixed to the brush chamber 200, and the high temperature heat and vibration transmitted through the rotor 5 and the brush chamber 200 The first fixing member 410 is inserted into the first insertion hole 122 to stably fix the position of the brush chamber 200 due to the high pressure fluid supplied to the second insertion hole 124, And includes a second fixing member 420.

Particularly, in this embodiment, since the first insertion hole 122 into which the first fixing member 410 is inserted and the second insertion hole 124 into which the second fixing member 420 is inserted are opened differently from each other The brush body 200 is fixed at different positions and orientations so that movement due to pressure fluctuations applied to the brush body 200 through the high-pressure fluid can be minimized and moved through the brush body 200 It is possible to maintain the fluid amount constant.

Further, the state in which the brush seal part 200 is fixed in both directions including the radial direction or the circumferential direction by the high-pressure fluid is stably maintained.

The fixing member 400 can be selectively used either as a bolt or as a pin because both the bolt or the pin are fixed to the packing body 100 through welding after welding outside the packing body 100. [

For example, bolts may be used for the first fixing member 410, pins may be used for the second fixing member 420, bolts may be used for both the first and second fixing members 410 and 420, And can be selectively used.

The first fixing member 410 and the second fixing member 420 may be made of a steel material that is not thermally expanded. In this case, the first and second fixing members 410 and 420 may be fixed only to the brush chamber 200 Conduct.

The first fixing member 410 includes a body 412 having a surface contact with the upper surface of the brush seal portion 200 and a head 414 formed on the upper surface of the body 412. The head 414 May be inserted into the first insertion hole 122 in a completely inserted manner.

The body 412 may be configured such that a thread is formed in a part of the lower end and is thermally expanded to thermally expand in the radial direction of the packing body 100. In this case, a part of the body 412 is inserted into the first insertion hole 122 And the thermal expansion is performed toward the radial direction of the packing body 100 only in a part of the lower end, so that the entire brush chamber 200 can be pressed. Accordingly, even when a pressure due to a high-pressure fluid is applied to the brush chamber 200, a gap between the rotor 5 and the brush 210 is not separated, and a constant gap is stably maintained.

The material for the body 412 is selectively used for the specific material through experiments in consideration of stable thermal expansion.

The second fixing member 420 is inserted into the second insertion hole 124 from the side of the packing body 100 and has a function of fixing the entirety of the brush seal part 200 in the circumferential direction of the packing body 100, It is possible to prevent the seal part 200 from moving in the circumferential direction along the insertion groove 110 to keep the gap between the outer circumferential surface of the rotor 5 and the brush 210 constant, Thereby maintaining a uniform movement of the wafer.

The second fixing member 420 is inserted in the center position between the first insertion holes 122 so as to be applied to the brush seal portion 200. The pressing force of the first fixing member 410 and the pressing force of the second fixing member 420 are maintained in an equilibrium state so that the brush seal unit 200 is stably fixed maintain.

More specifically, the pressing force applied to the brush seal portion 200 by the first fixing member 410 is applied in the radial direction of the brush seal portion 200 and is applied to the second fixing member 420 The pressing force is applied in the circumferential direction of the brush seal part 200.

At this time, when the distance between the spaced first fixing members 410 is L, the second fixing member 420 is fixed to the brush chamber 200 at a position of 1/2 * L, Is fixed to the insertion groove 110 in a state where the pressing force applied by the first fixing member 410 is kept constant at the tip end or the rear end of the insertion groove 110. [

Accordingly, the fixing force to the brush chamber 200 is relatively improved, and the occurrence of vibration due to the high-pressure fluid can be minimized.

The second fixing member 420 is positioned at the center of the thermal expansion member 300 disposed along the longitudinal direction of the brush seal part 200. In this case, when the thermal expansion member 300 is thermally expanded in the longitudinal direction, The entirety of the room 200 can be prevented from moving in the specific direction of the left or right direction, and the state in which it is positioned in the correct position can be stably maintained.

The fixing member 400 includes a tool insertion groove 402 formed for inserting a tool on an upper surface thereof and a tool corresponding to the shape of the tool insertion groove 402 is inserted to fix the mounting member 400 on the fixing member 400 And can be conveniently carried out. As a result, the workability of the operator is improved and the time required for installation and disassembly is shortened, thereby shortening the time required for assembling or disassembling the plurality of fixing members 400.

The support member 220 includes a first support plate 222 which is in close contact with one side of the brush 210 and a second support plate 224 which is in close contact with the other side. The first support plate 222 is provided with a guide groove 222a for guiding the flow of the fluid from the inside facing the brush 210 to the lower side of the brush 210 so that the flow of the high- To the gap between the lower end of the guide plate 210, thereby enabling stable transfer. Accordingly, when the high-pressure fluid is moved to the brush 210 via the first support plate 222, unnecessary eddy currents are minimized and the flow of the fluid to the lower end of the brush 210 can be induced.

For reference, the pressure on the right side with respect to the brush 210 is relatively higher than the pressure on the left side (PH), the left side corresponds to the lower pressure PL, and the flow of the fluid is shifted from right to left as indicated by the dotted arrow The brushes 210 prevent the fluid in the high-pressure region from leaking to the low-pressure region.

It is noted that the second support plate 224 has a thickness corresponding to that of the first support plate 222, but may be varied without necessarily being limited thereto. The second support plate 224 is positioned in close contact with one surface of the brush 210 to stably support the pressure of the high pressure fluid applied to the brush 210. Further, a slot groove (not shown) is formed at a position facing the thermal expansion member 300, thereby enabling stable installation and expansion of the thermal expansion member 300.

The brush 210 is formed of a plurality of bristles and is configured such that the first support plate 222 and the second support plate 224 are in close contact with each other with respect to the brush 210, As shown in FIG.

This is because the brush 210 directly or indirectly rubs with the rotor 5 and the stress is continuously applied to the brush 210 so that the lower end of the brush 210 is perpendicular to the rotor 5 To be placed in the insertion groove 110 in a state of being inclined at 45 degrees without being placed in the packing body 100 to minimize the stress applied to the rotor 5.

7 to 8, the thermal expansion member 300 is extended in the state of being closely attached along the longitudinal direction of the upper surface of the second support plate 224, and the heat transferred from the high- 100 in the circumferential direction.

The thermal expansion member 300 is disposed to be opposed to the second insertion hole 124 independently of each other, and the entire thermal expansion member 300 is thermally expanded in the longitudinal direction or selectively thermally expanded only at the front end and the rear end (See FIG. 8).

The distance between the thermal expansion member 300 and the second fixing member 420 is not particularly limited but is located at a position close to the thermal expansion member 300 so that the thermal expansion member 300 is kept pressed by the fixing member 400 .

A brush seal assembly according to another embodiment of the present invention will be described with reference to the drawings.

9 to 12, the brush seal assembly 1a includes an insertion groove 110 formed between the rotor 5 and the fixture and formed in the circumferential direction, and an insertion groove 110 And a second insertion hole (130) positioned at a different position from the first insertion hole (120) and opened toward the insertion groove (110), wherein the first insertion hole (100).

A brush body 210 including a brush 210 extending toward the rotor 5 (see FIG. 1) inserted into the insertion groove 110 and a support member 220 supporting the brush 210, A thermal expansion member 300 which is in close contact with a side surface of the support member 220 and thermally expands in a circumferential direction of the packing body 100; And a fixing member inserted into the first and second insertion holes 120 and 130 from the outside of the packing body 100 to maintain the fixed state of the brush seal part 200 in the radial direction and the circumferential direction of the packing body 100, (400).

Although the first insertion hole 120 and the second insertion hole 130 are both opened on the upper surface of the brush seal part 200 in the present embodiment, The first insertion holes 120 are spaced apart from each other and the second insertion holes 130 are positioned at intermediate positions between the first insertion holes 122 spaced apart from each other.

The first insertion hole 120 may be opened or deformed as shown in the figure and may be connected to the packing body 100 by the fixing member 400 inserted into the first insertion hole 120 and the brush seal part 200 ) May be varied for stable fixation.

The first insertion hole 120 is opened at the center of the upper surface of the brush seal part 200 and is spaced apart at regular intervals. When the fixing member 400 is inserted in a state orthogonal to the packing body 100, And the fixing force applied by the fixing member 400 is stably maintained regardless of the position.

The first insertion hole 120 is formed with a thread on the inner circumferential surface thereof and a fixing member 400 to be described later is screwed to stably fix the brush body 200 to the brush body 200 via the packing body 100.

The second insertion hole 130 is opened toward the inner side of the packing body 100 at a side position other than the upper side with respect to the outer circumferential surface of the packing body 100. The first insertion hole 120, Or at an intermediate position between the first insertion holes 120 spaced apart.

The second insertion hole 130 is open at a position of 1/2 * L, assuming a distance between the first insertion holes 120 is L, to enable fixing to the brush seal part 200.

The second insertion hole 130 may be open to one or both of the left and right sides of the front surface of the packing body 100. In this embodiment, the second insertion hole 130 is limited to the left side of the packing body 100 Explain that one position is variable.

The first and second insertion holes 120 and 130 may be threaded in an inner circumferential direction or may have threads formed only in the first insertion hole 120 and the second insertion hole 130 may be formed in a threadless shape.

The second insertion hole 130 is opened toward the thermal expansion member 300 but the second fixing member 420 is inserted without directly contacting the thermal expansion member 300.

The thermal expansion members 300 are disposed facing each other with respect to the second insertion hole 130. The thermal expansion members 300 are installed at the same length in the circumferential direction of the support member 220.

The thermal expansion member 300 is thermally expanded in the circumferential direction of the packing body 100 by conduction of the heat transferred from the high temperature fluid. The thermally expanding member 300 is disposed facing each other with respect to the second insertion hole 130, ) May be configured such that thermal expansion is performed in the longitudinal direction of the whole body, or thermal expansion is selectively performed only at the front end portion and the rear end portion.

The distance between the thermal expansion member 300 and the second fixing member 420 is not particularly limited but is located at a position close to the thermal expansion member 300 so that the thermal expansion member 300 is kept pressed by the fixing member 400 .

The fixing member 400 is fixed to the brush chamber 200 and is connected to the brush chamber 200 due to high temperature heat and vibration transmitted through the rotor 5 and high pressure fluid supplied to the brush chamber 200. [ A first fixing member 410 inserted into the first insertion hole 120 and a second fixing member 420 inserted into the second insertion hole 130 in order to fix the position of the unit 200 stably.

Particularly, in this embodiment, since the first insertion hole 120 into which the first fixing member 410 is inserted and the second insertion hole 130 into which the second fixing member 420 is inserted are differently opened, (200) are fixed at different positions so that the movement due to the pressure fluctuation applied to the brush seal part (200) through the high pressure fluid is minimized to reduce the amount of fluid moving through the brush seal part (200) It can be kept constant.

Further, the state in which the brush seal part 200 is fixed in both directions including the radial direction or the circumferential direction by the high-pressure fluid is stably maintained.

The fixing member 400 can be selectively used either as a bolt or as a pin because both the bolt or the pin are fixed to the packing body 100 through welding after welding outside the packing body 100. [

For example, bolts may be used for the first fixing member 410, pins may be used for the second fixing member 420, bolts may be used for both the first and second fixing members 400, And can be selectively used.

Referring to FIGS. 12 to 14, the first and second fixing members 410 and 420 may be made of a steel material that is not thermally expanded. In this case, the first and second fixing members 400, Only the fixation to the brush seal part 200 is performed.

The first fixing member 410 includes a body 412 having a surface contact with the upper surface of the brush seal portion 200 and a head 414 formed on the upper surface of the body 412. The head 414 May be inserted into the first insertion hole 122 in a fully inserted manner (see FIG. 14).

The body 412 may be configured such that a thread is formed in a part of the lower end and is thermally expanded to thermally expand in the radial direction of the packing body 100. In this case, a part of the body 412 is inserted into the first insertion hole 122 And the thermal expansion is performed toward the radial direction of the packing body 100 only in a part of the lower end, so that the entire brush chamber 200 can be pressed.

Accordingly, even when a pressure due to a high-pressure fluid is applied to the brush chamber 200, a gap between the rotor 5 and the brush 210 is not separated, and a constant gap is stably maintained. The material for the body 412 is selectively used for the specific material through experiments in consideration of stable thermal expansion.

The second fixing member 420 is inserted into the second insertion hole 130 and has a function of fixing the entirety of the brush seal part 200 in the circumferential direction of the packing body 100 and a function of fixing the brush seal part 200 in the insertion groove 130. [ So that the gap between the outer circumferential surface of the rotor 5 and the brush 210 is kept constant at all times to uniformly maintain the movement of the fluid through the brush chamber 200.

Since the second fixing member 420 is inserted at the center position between the spaced first insertion holes 120, the pressing force of the first fixing member 410 applied to the brush seal portion 200 and the pressing force of the second fixing member 410 420 are kept in an equilibrium state with respect to each other so that the brush seal portion 200 is stably fixed.

More specifically, the pressing force applied to the brush seal portion 200 by the first fixing member 410 is applied in the radial direction of the brush seal portion 200 and is applied to the second fixing member 420 The pressing force is also applied in the circumferential direction of the brush seal part 200.

At this time, when the distance between the spaced first fixing members 410 is L, the second fixing member 420 is fixed to the brush chamber 200 at a position of 1/2 * L, Is fixed to the insertion groove 110 in a state where the pressing force applied by the first fixing member 410 is kept constant at the tip end or the rear end of the insertion groove 110. [

Accordingly, the fixing force to the brush chamber 200 is relatively improved, and the occurrence of vibration due to the high-pressure fluid can be minimized.

The first fixing member 410 is pressed inward with respect to the radial direction of the packing body in a state in which the lower end of the first fixing member 410 is in close contact with the upper surface of the brush seal part 200, Is positioned at the center of the thermal expansion member 300 to prevent the packing body 100 from moving in the circumferential direction.

The second fixing member 420 is positioned at the center of the thermal expansion member 300 provided in the brush chamber 200. In this case, when the thermal expansion member 300 is thermally expanded in the longitudinal direction, Can be prevented from moving in the specific direction of the left or right direction, thereby stably maintaining the state in the correct position.

The fixing member 400 includes a tool insertion groove 402 formed for inserting a tool on an upper surface thereof and a tool corresponding to the shape of the tool insertion groove 402 is inserted to fix the mounting member 400 on the fixing member 400 And can be conveniently carried out. As a result, the workability of the operator is improved and the time required for installation and disassembly is shortened, thereby shortening the time required for assembling or disassembling the plurality of fixing members 400.

The support member 220 includes a first support plate 222 which is in close contact with one side of the brush 210 and a second support plate 224 which is in close contact with the other side. The first support plate 222 is provided with a guide groove 222a for guiding the flow of the fluid from the inside facing the brush 210 to the lower side of the brush 210 so that the flow of the high- To the gap between the lower end of the guide plate 210, thereby enabling stable transfer.

Accordingly, when the high-pressure fluid is moved to the brush 210 via the first support plate 222, unnecessary eddy currents are minimized and the flow of the fluid to the lower end of the brush 210 can be induced.

For reference, the pressure on the right side with respect to the brush 210 is relatively higher than the pressure on the left side (PH), the left side corresponds to the lower pressure PL, and the flow of the fluid is shifted from right to left as indicated by the dotted arrow The brushes 210 prevent the fluid in the high-pressure region from leaking to the low-pressure region.

It is noted that the second support plate 224 has a thickness corresponding to that of the first support plate 222, but may be varied without necessarily being limited thereto. The second support plate 224 is positioned in close contact with one surface of the brush 210 to stably support the pressure of the high pressure fluid applied to the brush 210. In addition, a slot groove is formed at a position facing the thermal expansion member 300, thereby enabling stable installation and expansion of the thermal expansion member 300.

The brush 210 is formed of a plurality of bristles and is configured such that the first support plate 222 and the second support plate 224 are in close contact with each other with respect to the brush 210, As shown in FIG.

This is because the brush 210 directly or indirectly rubs with the rotor 5 and the stress is continuously applied to the brush 0 so that the lower end of the brush 210 is perpendicular to the rotor 5 In order to minimize the stress applied to the rotor 5 by positioning it in the insertion groove 110 at a state inclined by 45 degrees without being placed in the packing body 100. [

The use state of the brush seal assembly according to one embodiment of the present invention will be described with reference to the drawings.

2 or 15, the brush seal part 200 is fixed in the radial direction and the circumferential direction of the packing body 100 by the first fixing member 410 and the second fixing member 420 Is maintained.

Pressure fluid is directly applied to the brush chamber during the movement of the high-pressure fluid through the brush chamber 200, and the pressing force is applied to the Z-axis upward direction through the rotor 5.

In this case, the first fixing member 410 presses the upper surface of the support member 220 and the brush 210 in the circumferential direction as shown by the arrows to maintain a stable state in the entire radial direction of the brush seal part 200 And the second fixing member 420 maintains the pressing force fixed at the side center of the brush seal part 200. [

The second fixing member 420 can prevent the end portion of the second fixing member 420 from contacting with the second supporting member 420 even when a force is applied to move the brush seal portion 200 forward or backward with respect to the circumferential direction, 220), thereby stably fixing the entirety of the brush seal part 200 in the circumferential direction.

Accordingly, it is possible to prevent the movement of the brush seal unit 200 due to the high-pressure fluid, thereby maintaining the flow of the gas through the brush 210 constantly, thereby improving the efficiency of the object in which the brush seal assembly is installed, Prevent.

The use state of the brush seal assembly according to an embodiment of the present invention will be described with reference to the drawings.

9 or 16, the brush seal part 200 is fixed in the radial direction and the circumferential direction of the packing body 100 by the first fixing member 410 and the second fixing member 420 Is maintained.

Pressure fluid is directly applied to the brush chamber during the movement of the high-pressure fluid through the brush chamber 200, and the pressing force is applied to the Z-axis upward direction through the rotor 5.

In this case, the first fixing member 410 presses the upper surface of the support member 220 and the brush 210 in the circumferential direction as shown by the arrows to maintain a stable state in the entire radial direction of the brush seal part 200 The second fixing member 420 is fixed at a position different from the first fixing member 410 with respect to the radial direction of the entire brush seal part 200 by pressing against the upper surface of the brush seal part 200 maintain.

Since the first and second fixing members 400 are partially fixed in the radial direction and fixed in the circumferential direction of the brush seal part 200, the brush seal part 200 can not be radially or circumferentially Even if a force is applied to the movable member.

Accordingly, it is possible to prevent the movement of the brush seal unit 200 due to the high-pressure fluid, thereby keeping the flow of the gas through the brushes 210 constant, thereby improving the efficiency of the object provided with the brush seal assembly 1a, .

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit of the invention as set forth in the appended claims. The present invention can be variously modified and changed by those skilled in the art, and it is also within the scope of the present invention.

1, 1a: brush seal assembly
3: Fixture
5: Rotor
100: Packing body
110: insertion groove
112: insertion hole
122, 124: first and second insertion holes
200: Brush chamber part
210: Brush
220: Support member
222, 224: first and second support plates
222a: guide groove
300: thermal expansion member
400: Fixing member
402: Tool insertion groove
410: first fixing member
420: second fixing member
412: Body
414: Head

Claims (26)

A packing body including an insertion groove formed between the rotor and the fixture and formed inside the circumferential direction, and an insertion hole opened at different positions and directions toward the insertion groove;
A brush chamber extending from the insertion groove to the rotation body, and a support member for supporting the brush;
A thermal expansion member in close contact with a side surface of the support member and performing thermal expansion in a circumferential direction of the packing body; And
And a fixing member inserted into the first and second insertion holes from the outside of the packing body to maintain the fixed state of the brush seal part in the radial direction and the circumferential direction of the packing body. The method according to claim 1,
The insertion hole
A first insertion hole opened toward the insertion groove in the radial direction of the packing body;
And a second insertion hole opened from the outer side of the packing body toward the insertion groove. 3. The method of claim 2,
The second insertion hole
Wherein the first and second insertion holes are spaced apart at regular intervals. 3. The method of claim 2,
The second insertion hole
And the second insertion hole is opened at an intermediate position between the first insertion holes. 3. The method of claim 2,
The second insertion hole
And the opening is opened in the middle of the longitudinal direction of the packing body. 3. The method of claim 2,
The second insertion hole
And both of the left and right sides of the packing body are opened with respect to the front surface of the packing body. 3. The method of claim 2,
The first insertion hole
And the opening is orthogonal to the packing body. The method according to claim 1,
The first insertion hole
Wherein a thread is formed in the inner circumferential direction. 3. The method of claim 2,
The first and second insertion holes
Wherein a thread is formed in the inner circumferential direction. 4. The method according to any one of claims 1 to 3,
Wherein:
A first fixing member inserted into the first insertion hole;
And a second fixing member inserted into the second insertion hole. 11. The method of claim 10,
Wherein the first fixing member comprises:
A body having a surface contact with an upper surface of the brush seal part;
And a head formed on an upper surface of the body, wherein the head is fully inserted into the first insertion hole. 12. The method of claim 11,
The body
Wherein a thread is formed in a lower part of the section and is made of a thermal expansion material to thermally expand in a radial direction of the packing body. 11. The method of claim 10,
Wherein the brush seal assembly comprises:
And a third insertion hole formed on an upper surface of the brush seal portion such that a lower end of the first fixing member is partially inserted. 11. The method of claim 10,
Wherein the first fixing member is a bolt, and the second fixing member is a pin. 11. The method of claim 10,
Wherein the first and second fixing members are bolts. The method according to claim 1,
Wherein:
And a tool insertion groove formed on the upper surface for insertion of the tool. The method according to claim 1,
Wherein the support member comprises:
A first support plate having a guide groove formed on one side of the brush and having a guide groove for guiding the flow of the fluid toward the lower side of the brush on the inner side facing the brush;
And a second support plate which is in close contact with the brush in a state facing the first support plate and is formed at a position facing the thermal expansion member. The method according to claim 1,
The thermal expansion member
Wherein the first and second insertion holes are disposed facing each other with respect to the insertion hole. A first insertion hole which is located between the rotating body and the fixed body and is formed on the inner side in the circumferential direction, a first insertion hole which is radially formed on the outer peripheral surface and which is opened toward the insertion groove, A packing body including a second insertion hole which is opened toward the body;
A brush chamber extending from the insertion groove to the rotation body, and a support member for supporting the brush;
A thermal expansion member in close contact with a side surface of the support member and performing thermal expansion in a circumferential direction of the packing body; And
And a fixing member inserted into the first and second insertion holes from the outside of the packing body to maintain the fixed state of the brush seal part in the radial direction and the circumferential direction of the packing body. 20. The method of claim 19,
The second insertion hole
And is open toward the thermal expansion member. 20. The method of claim 19,
The second insertion hole
Wherein the first and second insertion holes are spaced apart at regular intervals. 20. The method of claim 19,
The thermal expansion member
Wherein the first and second insertion holes are disposed facing each other with respect to the second insertion hole. 20. The method of claim 19,
Wherein:
A first fixing member inserted into the first insertion hole;
And a second fixing member inserted into the second insertion hole. 20. The method of claim 19,
Wherein the first fixing member comprises:
The lower end is pressed toward the inside in the radial direction of the packing body in a state where the lower end is in close contact with the upper surface of the brush seal part,
Wherein the second fixing member comprises:
And is positioned at the center of the thermal expansion member to prevent the packing body from moving in the circumferential direction. 20. The method of claim 19,
Wherein the first fixing member comprises:
A body having a surface contact with an upper surface of the brush seal part;
And a head formed on an upper surface of the body, wherein the head is fully inserted into the first insertion hole. 26. The method of claim 25,
The body
Wherein a thread is formed in a part of the lower part and is made of a thermal expansion material to thermally expand in a radial direction of the packing body.

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