KR20150137193A - Turbine with Foreign substance collecting function - Google Patents

Abstract

A turbine having a foreign substance collecting function according to an embodiment of the present invention comprises: a body member; a rotating member which is coupled to the body member to be rotated; a leakage prevention member which is provided to be adjacent to the outer end of the rotating member and is coupled to the body member to form a groove part; and a collecting member which is coupled to the inner side of the groove part, wherein the collecting member has an inlet part where floating foreign substances, which have centrifugal force by the rotation of the rotating member, flows thereinto by cooperating with the groove part, and a receiving space having a larger width than the inlet part. Therefore, the present invention reduces maintenance costs by preventing damage to the turbine through the collection of foreign substances.

Description

{Turbine with Foreign substance collecting function}

The present invention relates to a turbine having a foreign matter collecting function, and more particularly, to a turbine having a foreign matter collecting function, and more particularly, to a turbine having a centrifugal force, .

A steam turbine is a machine that rotates a rotor by using high-temperature, high-pressure steam and produces electricity from a generator connected to the same shaft. The steam turbine can be roughly divided into a body member, which is a diaphragm that guides the flow of steam, and a rotating member, which is equipped with a blade and rotates the rotor.

Here, the steam serves to rotate the rotary member to produce electricity. If such steam leaks without being used for rotating the rotary member, there is a problem that the efficiency of the electric production is lowered.

That is, when the steam passes through the inside of the turbine, a portion of the steam leaks into a gap between the body member and the rotary member. The steam leakage portion includes an outer end of the blade, a packing of the body member, , And the inner part of the blade (root part). This leaked steam does not rotate the turbine, which is a loss of electricity production.

In order to prevent such leakage of the steam, a spill strip is provided at the end of the body outside the blade.

On the other hand, the steam for rotating the turbine flows through the connection pipe from the boiler to the turbine. When the inside of the pipe is corroded, a scale is generated, and foreign substances such as scales are included in the steam.

The foreign matter introduced into the turbine collides with the blade surface and damages the blade surface. Damage to the surface of the blade causes loss of the steam path roughness and loss due to an area change, which causes a problem of cracking of the blade.

As shown in FIG. 1, the leakage preventing member 30 'has a groove portion H between the leakage preventing member 30' and the body member 10 ' The leakage preventing member 30 'is damaged while colliding with the foreign matter.

In other words, the foreign substances which have entered the groove H can not escape to the downstream side, but are eroded and damaged by continuously colliding with the blade and the end portion of the leakage preventing member 30 '(the portion joined with the body member).

If the erosion is severe, the pieces of the leakage preventing member 30 'are also detached. The pieces of the leakage preventing member 30' that have been released in this way are introduced into the steam passage to collide with the blades and cause large damage to the blades and the body member I can not.

In addition, there is a problem that the maintenance cost increases because the leakage preventing member replacement work and the blade roughness improvement work must be performed every time the turbine is maintained.

Therefore, it is necessary to study a turbine having a foreign matter collecting function to prevent damage by the foreign matter.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a turbine having a foreign matter collecting function capable of reducing the maintenance cost by preventing the damage of the turbine by collecting foreign matter generated in the turbine.

A turbine having a foreign matter collecting function according to an embodiment of the present invention includes a body member, a rotating member rotatably coupled to the body member, a turbine provided adjacent to an outer end of the rotating member, And a collecting member coupled to the inside of the groove portion, wherein the collecting member includes an inlet portion in which the floating foreign matter having centrifugal force is introduced by the rotation of the rotating member in cooperation with the groove portion, and an inlet portion The accommodation space having a large width can be formed.

The collecting member of the turbine having the foreign matter collecting function according to an embodiment of the present invention includes a first impact surface provided to be inclined inwardly of the groove portion and includes a neighboring end provided adjacent to the rotating member can do.

The collecting member of the turbine having the foreign matter collecting function according to an embodiment of the present invention includes a center portion connected to the adjacent end portion and formed with a second impact surface provided to be inclined in a direction opposite to the first impact surface .

In addition, in the turbine having the foreign matter collecting function according to the embodiment of the present invention, the adjacent extended end of the collecting member may be provided with an extended receiving groove formed to be open to the receiving space.

In addition, the collecting member of the turbine having the foreign matter collecting function according to an embodiment of the present invention may be provided with a bumper jaw protruding into the receiving space, and may include an inner end coupled with the body member.

Further, the bumper jaw of the turbine having the foreign matter collecting function according to an embodiment of the present invention may be provided with a magnet.

In addition, the collecting member of the turbine having the foreign matter collecting function according to an embodiment of the present invention is provided in the form of a ring that surrounds the outer end of the rotating member, and the groove portion is divided into a portion divided in the circumferential direction An isolation wall can be formed.

In the turbine having the foreign matter collecting function of the present invention, the collecting member can be coupled to form a receiving space having a width larger than that of the inlet portion, so that foreign matter can be advantageously converged into the receiving space.

As a result, it is possible to collect foreign substances floating inside the turbine, and it is possible to prevent the rotation member, the leakage preventing member, and the like of the turbine from being damaged by the foreign matter.

Therefore, it is possible to reduce the maintenance cost of the turbine, and it is possible to prevent the problem that the operation efficiency of the turbine due to the shutdown of the turbine is reduced.

1 shows a groove between a leakage preventing member and a body member in a conventional turbine.
2 is a cross-sectional view of a turbine having a foreign matter collecting function according to the present invention.
Figs. 3 to 5 are enlarged cross-sectional views of portion M of Fig.
6 is a cross-sectional view showing an embodiment in which, in a turbine having a foreign matter collecting function according to the present invention, the collecting member includes accommodating extended corrugations.
7 is a view showing an embodiment in which a collecting member of a turbine having a foreign matter collecting function according to the present invention includes an isolating wall.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings. 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 or scope of the inventive concept. Other embodiments falling within the scope of the inventive concept may readily be suggested, but are also considered to be within the scope of the present invention.

The same reference numerals are used to designate the same components in the same reference numerals in the drawings of the embodiments.

When the foreign matter f having centrifugal force is moved to the outside of the rotary member 20 by the rotary member 20 to rotate the foreign matter f in the turbine having the foreign matter f collection function according to the present invention, I to the accommodation space S through the openings.

That is, in the turbine having the foreign matter (f) collecting function of the present invention, the collecting member 40 can be coupled so that the receiving space S having a width larger than the inlet portion I is formed, The foreign matter f can be converged.

This makes it possible to collect the foreign matter f floating inside the turbine and to prevent the rotating member 20 and the leakage preventing member 30 of the turbine from being damaged by the foreign matter f .

Therefore, the maintenance cost of the turbine can be reduced, and the problem of the reduction of the turbine operation efficiency due to the shutdown of the turbine can be prevented.

2 is an enlarged view of a portion M of FIG. 2, and also shows a cross-sectional view showing a minimum condition in which a foreign matter (f) is introduced. FIG. 2 is a sectional view showing a turbine having a foreign matter to be.

6 is a cross-sectional view showing an embodiment in which, in the turbine having the foreign matter (f) collecting function of the present invention, the collecting member 40 includes the receiving expanding cores 41b.

2, 3 and 6, a turbine having a foreign matter (f) collecting function according to an embodiment of the present invention includes a body member 10, a rotating member rotatably coupled to the body member 10 A leakage preventing member 30 which is provided adjacent to an outer end of the rotary member 20 and is coupled to the body member 10 to form a groove H and And a collecting member 40 which collects the foreign matter f having a centrifugal force by rotation of the rotary member 20 in cooperation with the groove portion H, I and a receiving space S that is wider than the inlet portion I can be formed.

The collecting member 40 of the turbine having the foreign matter f collecting function according to an embodiment of the present invention is formed with a first impact surface 41a provided to be inclined inward of the groove portion H, And a proximal end 41 provided adjacent to the rotary member 20. [

In addition, in the turbine having the foreign matter (f) collecting function according to the embodiment of the present invention, the adjacent extended end 41 of the collecting member 40 is provided with the receiving extension bore 41b formed to be open to the receiving space S, Can be provided.

The body member 10 may serve as a body to which a rotating member 20, a leakage preventing member 30, a collecting member 40, and the like to be described later are coupled. In addition, it may include configurations that may be present in a typical steam turbine.

That is, it may include an outer casing, an inner casing, or the like, and the inner casing may be provided with a steam guide or the like through which steam is introduced and guided. Such a steam guide may be connected to a superheater or reheater of a boiler or other steam turbine to introduce steam.

The rotary member 20 can be rotated while passing through the steam. As a result, electric energy can be produced in the generator or the like connected to the rotary member 20. [

That is, the rotary member 20 is rotatably coupled to the body member 10. For this purpose, the rotary member 20 and the rotary shaft portion 22 may be provided. It is.

Here, the blade portion 21 may be rotated while passing the steam, and the rotary shaft portion 22 may be coupled with the blade portion 21 to be a rotation axis of the blade portion 21 .

The leakage preventing member 30 may prevent the steam from escaping between the rotary member 20 and the body member 10. [ That is, the end of the rotary member 20 outside the blade 21 is provided adjacent to the body member 10, but is not provided completely in close contact with the blade member 21, A certain gap is formed between the end of the outer side of the body member 10 and the body member 10.

Since the steam can escape through such a gap and the steam does not escape by pushing the blade portion 21 of the rotary member 20 to rotate, the generation efficiency such as the production of electric energy by the steam is lowered .

In order to reduce such a problem, the leakage preventing member (30) is provided in the gap to guide the steam to the rotary member (20).

For this, the leakage preventing member 30 may be provided to be coupled to the body member 10 adjacent to the outer end of the rotating member 20. [

The leakage preventing member 30 is coupled to the body member 10 so that a groove H is formed between the leakage preventing member 30 and the body member 10.

The leakage preventing member 30 is damaged by the foreign matter f floating in the turbine after the collision and the blade portion of the rotating member 20 adjacent to the groove portion H 21).

In order to prevent this, it is possible to collect the foreign matter (f) by providing a collecting member (40) to be described later.

The collecting member 40 is provided to be coupled to the groove H, and by providing a specific shape, the foreign matter f can be collected and collected.

That is, the foreign matter f is generated by the corrosion of the inside of the turbine, and the foreign matter f is centrifugally moved by being rotated on the rotating air current generated by the rotation of the rotating member 20.

The foreign matter f is moved to the outside of the rotary member 20 by the centrifugal force and the leakage preventing member 30 and the rotation preventing member 30 are attached to the apparatus body 10 adjacent to the outer end of the rotary member 20. [ The foreign matter f flows into the accommodating space S to be described later formed by the collecting member 40 provided in the groove portion H because the groove portion H formed in cooperation with the groove portion H.

At this time, only a part of the introduced foreign matter f escapes from the accommodating space S, and a foreign matter f larger than the escaped foreign matter f remains in the accommodating space S. Such action repeatedly occurs, so that the foreign matter f is converged into the receiving space S and is collected.

For this purpose, the collecting member 40 can form an inlet I and a receiving space S in cooperation with the groove H, and in particular, the inlet I can be formed in the receiving space S, It is possible to reduce the rate at which the foreign matter (f) introduced into the accommodation space (S) flows out through the inlet (I).

Furthermore, since the foreign matter f has a larger force to be introduced into the inlet portion I due to the centrifugal force, the ratio of the foreign matter f that returns to the inlet portion I due to the chain collision in the accommodation space S Less.

The foreign matter f that has escaped from the inlet portion I also flows into the accommodation space S by centrifugal force so that the floating foreign matter f is converged into the accommodation space S, have.

Here, the collecting member 40 may include a proximal end portion 41, a central portion 42, an inside end portion 43, an isolation wall 44, and the like.

The adjacent end portion 41 refers to a portion of the collecting member 40 closest to the rotary member 20 and the first impact surface 41a on which the foreign matter f first collides is formed on the adjacent end portion 41, Can be provided.

The first impact surface 41a is inclined inwardly of the groove portion H so that the foreign matter f colliding with the first impact surface 41a is guided to the inlet portion I, can do.

It may also be a problem that the incident angle a of the foreign matter f colliding with the first impact surface 41a and the range in which the inflow position can enter the inlet portion I is also problematic. First, it is assumed that the incident angle (a) and the reflection angle (a) are the same for the foreign matter (f) reflected after the collision.

The incident angle a and the inflow position may be presented in various ranges according to the gap W of the inlet portion I and the inclination angle of the first impact surface 41a.

For example, when the inflow position of the foreign matter f is the center portion of the first impact surface 41a and the incident path is horizontal to the wall surface of the groove portion H, Is equal to the inclination angle of the first impact surface (41a) at the vertex of the adjacent end portion (41).

If the distance between the vertex of the adjacent end portion 41 and the inlet portion I is defined as an inlet distance L in a direction parallel to the wall surface of the groove portion H, (L / 2) of the entrance distance (L).

The path of the second collision with the wall surface of the groove portion (H) reflected and moved by the foreign matter (f) reflected from the first collision surface (41a) by collision is shifted to the inside of the inlet portion (I) For this, the following formula must be satisfied.

{0.5L x tan (a) + W} x cot (2a) > 0.25L

That is, when the foreign matter f collides against the central portion of the first impact surface 41a in a direction parallel to the wall surface of the groove H, the entrance distance L And it must collide against the wall surface of the groove portion (H) close to the bottom surface of the groove portion (H).

If the relationship with the incidence angle is judged based on this assumption, the above relationship is established.

In addition, a receiving extension bore 41b may be further formed in the adjacent end portion 41. [ That is, since the receiving extension bore 41b is formed in the adjacent end portion 41 in the form of a valley formed so as to open to the receiving space S, it can serve to widen the receiving space S .

Further, the first collision surface 41a of the proximal end portion 41 is provided to be inclined inward of the groove portion H, and the accommodating extending ribs 41b are formed in a shape opened toward the accommodating space S Therefore, the foreign matter (f) introduced into the receiving extension bore (41b) collides with the receiving space (S) again.

This is similar to the principle of catching fish and the portion of the adjacent end 41 adjacent to the inlet I to the inlet I is provided inclined towards the inlet I, (I), but the opposite part going out through the inlet part (I) is not led to the inlet part (I) but is guided to the receiving extended valley (41b).

The center portion 42 may provide the second impact surface 42a as a portion where the foreign matter f flowing into the inlet portion I collides. The description of the center portion 42 will be described later with reference to FIG.

The inner end portion 43 may be coupled to the body member 10 by a bolt connection B or the like as a portion where the collecting member 40 is engaged with the body member 10, 43 may be provided with a bumper jaw 43a for enhancing the convergence effect of the foreign matter f by reducing the centrifugal force of the foreign matter f by colliding with the foreign matter f. A detailed description thereof will be given later with reference to Fig.

The isolation wall 44 may prevent the foreign matter f from rotating along the collecting member 40 provided in a ring shape. A detailed description thereof will be given later with reference to Fig.

FIG. 4 is an enlarged cross-sectional view of the portion M of FIG. 2, showing the foreign matter f colliding with the second impact surface 42a of the central portion 42. FIG.

4, the collecting member 40 of the turbine having the foreign matter f collecting function according to an embodiment of the present invention is connected to the adjacent end portion 41, And a central portion 42 formed with a second impact surface 42a provided obliquely to the opposite direction.

That is, the center portion 42 can provide the second impact surface 42a as a portion where the foreign matter f that has flowed into the inlet portion I collides with the inlet portion I, The foreign matter (f) can be further moved to the inside of the accommodation space (S).

In other words, since the second impact surface 42a is provided to be inclined in the direction opposite to the first impact surface 41a, the traveling direction of the foreign matter f after the impact is guided to the inside of the accommodation space S It can be.

The center portion 42 may not be provided when the receiving extension rib 41b is formed at the adjacent end portion 41 as a portion between the adjacent end portion 41 and an inner end portion 43 described later.

Fig. 5 is an enlarged cross-sectional view of portion M of Fig. 2, showing the foreign matter f colliding with the bumper jaw 43a of the inside end portion 43. Fig.

5, the collecting member 40 of the turbine having the foreign matter (f) collecting function according to the embodiment of the present invention is provided with a bumper jaw 43a protruding into the receiving space S, And an inner end 43 coupled with the body member 10.

Further, the bumper jaw 43a of the turbine having the foreign matter (f) collecting function according to an embodiment of the present invention may be provided with a magnet.

That is, the inside end portion 43 is a portion where the collecting member 40 is engaged with the body member 10, and can be coupled to the body member 10 by a bolt connection B or the like.

Particularly, the inner end portion 43 may be provided with a bumper jaw 43a for enhancing the convergence effect of the foreign matter f by reducing the centrifugal force of the foreign matter f by colliding with the foreign matter f.

That is, the bumper jaw 43a protrudes into the accommodation space S, which is a groove portion H between the body member 10 and the collecting member 40, The centrifugal force of the foreign matter (f), which is a driving force of movement, is reduced by colliding with the bottom of the groove portion (H) and the bumper jaw (43a) and colliding with one surface of the bumper jaw (43a) .

In addition, if only the bumper jaw 43a is provided to be formed of a magnet, the foreign matter f of the metallic material in the foreign matter f can be reduced by the magnetic force even by the centrifugal force and finally attached to the bumper jaw 43a So that it can be collected.

Further, since the foreign matter (f) is often formed by the material of the metallic material inside the turbine being removed, it can be expected that the effect on the increase of the trapping effect of the foreign matter (f) will be large.

Fig. 7 is a view showing an embodiment in which the collecting member 40 of the turbine having the foreign matter (f) collecting function of the present invention includes the isolating wall 44. Fig.

7, the collecting member 40 of the turbine having the foreign matter (f) collecting function according to the embodiment of the present invention is provided in the form of a ring surrounding the outer end of the rotating member 20, An isolation wall 44 for dividing the groove H may be formed at a portion where the groove H is divided at regular intervals.

That is, the isolation wall 44 may prevent the foreign matter f from rotating along the collecting member 40 provided in a ring shape.

In other words, since the foreign matter f has a centrifugal force due to the rotation flow of the rotating member 20, the rotating flow of the foreign matter f is induced by the rotation of the rotating member 20, And is rotated through the collecting member (40).

At this time, by providing the isolation wall 44, it is possible to reduce the centrifugal force due to collision when the foreign matter f is rotated, and to guide the foreign matter f to be accommodated in the collecting member 40.

That is, the bumper jaw 43a serves to reduce the radial movement of the foreign matter f to move outwardly by the centrifugal force, and the separating wall 44 is formed so that the foreign matter f is moved in the circumferential direction And to reduce the movement to move in the direction.

The isolation wall 44 may be provided with a space S formed between the collecting member 40 and the body member 10 in the groove H at a predetermined interval in the circumferential direction.

The separation wall 44 may be formed with a thread groove and may be bolted to the body member 10 to couple the divided collection member 40 to the body member 10. [ have.

10: device body 20: rotating member
21: blade portion 22: rotating shaft portion
30: leakage preventing member 40: collecting member
41: adjacent end 41a: first impact surface
41b: Expansion column 42:
42a: second impact surface 43: inner end
43a: bumper chin 44: isolation wall

Claims (7)

Body member;
A rotating member rotatably coupled to the body member;
A leakage preventing member provided adjacent to an outer end of the rotating member and coupled to the body member to form a groove; And
A collecting member coupled to the inside of the groove;
/ RTI >
Wherein the collecting member cooperates with the groove,
An inlet portion into which floating foreign matter having a centrifugal force flows by the rotation of the rotary member, and a foreign matter collecting function to form a receiving space having a width larger than that of the inlet portion. The method according to claim 1,
The collecting member
A proximal end provided with a first impact surface formed to be inclined inwardly of the groove and provided adjacent to the rotational member;
A turbine having a foreign matter collecting function. 3. The method of claim 2,
The collecting member
A center portion connected to the adjacent end portion and having a second impact surface provided to be inclined in a direction opposite to the first impact surface;
A turbine having a foreign matter collecting function. 3. The method of claim 2,
A receiving extension bone formed at the proximal end portion to be opened to the receiving space;
A turbine having a foreign matter collecting function. The method according to claim 1,
The collecting member
A bumper jaw projecting into the receiving space is provided, and an inner end coupled with the body member;
A turbine having a foreign matter collecting function. 6. The method of claim 5,
Wherein the bumper jaw is provided with a magnet. The method according to claim 1,
The collecting member
A ring-shaped portion surrounding an outer end of the rotary member,
A turbine having a foreign matter collecting function in which an isolating wall for dividing the groove portion is formed at a portion that is divided at regular intervals in a circumferential direction.

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