The present application claims priority to Korean Patent Application No. 10-2022-0162829, filed on Nov. 29, 2022, the entire contents of which are incorporated herein for all purposes by this reference.
The present disclosure relates to a connection tube support of a waste heat recovery boiler and a waste heat recovery boiler including the same. More particularly, the present disclosure relates to a connection tube support of a waste heat recovery boiler and a waste heat recovery boiler including the same, wherein the connection tube support supports a connection tube unit, which is disposed inside the waste heat recovery boiler and exchanges heat between a fluid flowing inside and exhaust gas flowing outside.
In general, a waste heat recovery boiler constitutes, together with a gas turbine system and a steam turbine system, a combined power generation system. The waste heat recovery boiler is often used as a subsidiary system to recover the heat of the combustion gas exhausted after driving the gas turbine and drive the steam turbine again.
Such a waste heat recovery boiler is called a heat exchanger together with a nuclear steam generator, a feed water heater, a condenser, an evaporator, and the like and, as shown in
Due to the presence of high-flow energy, the combustion gas passing through the inside of the fin tube 10 requires rigid attachment to the header 60. This prevents any potential damage caused by vibration waves generated by the internal flow of the combustion gas. The header 60 serves to collect the combustion gas flowing in through the fin tube 10.
Here, given the considerable length of the fin tube 10, the fin tube support 30 is installed on the inner wall surface of a boiler body to securely fix the fin tube 10 at an intermediate position along its length. The fin tube support 30 has a plurality of insertion holes 40 that allow the fin tube 10 to pass through and be securely fixed in please.
When the fin tube 10 vibrates due to the internal flow of the combustion gas or thermal deformation occurs in the fin tube 10 due to high temperature and high pressure of the combustion gas during the operation of the waste heat recovery boiler, a phenomenon can occur where the fin 20 becomes restricted and caught on the fin tube support 30 as shown in
Meanwhile, in the related art, when the vibration and thermal deformation occur in the fin tube 10, the above problems have been solved by drilling the insertion hole 40 to be a little larger than the diameter of the fin tube 10, so that the fin tube 10 may move in an axial direction through the inner space of the insertion hole 40 as shown in
The foregoing is intended merely to aid in the understanding of the background of the present disclosure, and is not intended to mean that the present disclosure falls within the purview of the related art that is already known to those skilled in the art.
Accordingly, the present disclosure has been made keeping in mind the above problems occurring in the related art, and an objective of the present disclosure is to provide a connection tube support of a waste heat recovery boiler and a waste heat recovery boiler including the same, which are capable of stably supporting a connection tube preventing damage to the connection tube due to the motion even in situations of thermal-expansion-induced movements of the connection tube through which a fluid flows exchanging heat with exhaust gas and of a tube sheet supporting the connection tube.
In order to achieve the above objective, according to the present disclosure, there may be provided a connection tube support of a waste heat recovery boiler supporting a connection tube unit having a plurality of connection tubes that is disposed inside a waste heat recovery boiler and performs heat exchange between a fluid flowing inside and exhaust gas flowing outside, the connection tube support including: a header storing fluid flowing through the connection tube unit and supporting one end of the connection tube unit by being connected to one end of the connection tube unit; and a tube sheet supporting a circumferential surface of each of the plurality of connection tubes, wherein the tube sheet may have the plurality of connection tubes passing therethrough and be provided with a plurality of support holes respectively supporting circumferential surfaces of the plurality of connection tubes passing therethrough.
In the connection tube support of a waste heat recovery boiler according to the present disclosure, the header and the tube sheet may be installed on an inner wall of a casing part of the waste heat recovery boiler, wherein a plurality of the tube sheets may be installed to be spaced apart from each other in a longitudinal direction of the connection tube unit.
Each of the support holes may be in a long-hole shape.
A width (W) of each of the support holes may be W=D+a compared with an outer diameter (D) of each of the connection tubes, and a length (L) of each of the support holes may be longer than the outer diameter (D) of each of the connection tubes, wherein the length (L) of each of the support holes may be D≤L≤bD compared with the outer diameter (D) of each of the connection tubes, a range of “a” may be 1 mm≤a≤3 mm, and a range of “b” may be 1.3≤b≤1.7.
When the tube sheet pertains to a condition of moving in an upper direction according to a thermal expansion analysis thereon, the connection tube may be positioned on an upper side part of the support hole.
When the tube sheet pertains to a condition of moving in upper and lower directions according to a thermal expansion analysis thereon, the connection tube may be positioned in a central part of the support hole.
When the tube sheet pertains to a condition of moving in a lower direction according to a thermal expansion analysis thereon, the connection tube may be positioned on a lower side part of the support hole.
The plurality of support holes may be disposed in a plurality of rows on the tube sheet. Wherein a first row and a second row are adjacent to each other, the plurality of support holes in a second row may be positioned between the plurality of support holes in the first row.
Wherein a plurality of support holes is provided in a third row which is adjacent to the second row, the plurality of support holes in the third row may be positioned on the same line as the plurality of support holes in the first row, and wherein a plurality of support holes is provided in a fourth row which is adjacent to the third row, the plurality of support holes in the fourth row may be positioned on the same line as the plurality of support holes in the second row.
In addition, there may be provided a waste heat recovery boiler, the boiler including: a casing part providing a flow path through which exhaust gas flows; a connection tube unit disposed inside the casing part and having a plurality of connection tubes provided to be perpendicular to a flow direction of the exhaust gas inside the casing part, the connection tube unit configured to perform heat exchange between a fluid flow inside the connection tube unit and the exhaust gas; and a connection tube support supporting the connection tube unit that is disposed inside the casing part and exchanges heat with a fluid flowing inside and exhaust gas flowing outside, wherein the connection tube support may include: a header storing fluid flowing through the connection tube unit and supporting one end of the connection tube unit by being connected to one end of the connection tube unit; and a tube sheet supporting a circumferential surface of each of the plurality of connection tubes, wherein the tube sheet may have the plurality of connection tubes passing therethrough and be provided with a plurality of support holes respectively supporting circumferential surfaces of the plurality of connection tubes passing therethrough.
As described above, according to a connection tube support of a waste heat recovery boiler and a waste heat recovery boiler including the same, even when a motion of the connection tube through which a fluid that exchanges heat with exhaust gas flows and a tube sheet supporting the connection tube occurs due to thermal expansion, the connection tube can be stably supported while flexibility for the motion thereof is secured by the long hole-shaped support hole provided in the tube sheet.
The above and other objectives, features, and other advantages of the present disclosure will be more clearly understood from the following detailed description when taken in conjunction with the accompanying drawings, in which:
Hereinafter, exemplary embodiments according to the present disclosure will be described in detail with reference to the accompanying drawings. Prior to this, it is noted that terms or words used in the present specification and claims should not be construed as being limited to the usual or dictionary meaning because, on the basis of the principle that the inventor may define the concept of the terms in order to explain his/her invention in the best way, the terms and words should be interpreted as meaning and concept consistent with the technical idea of the present disclosure.
With reference to
The casing part 1100 is provided inside thereof with the connection tube unit 1200 composed of a plurality of connection tubes disposed in a direction perpendicular to the flow direction of exhaust gas, wherein the plurality of connection tubes 1210 included in the connection tube unit 1200 is partitioned into a plurality of sections, and the plurality of connection tubes 1210 partitioned above is classified into superheaters, evaporators, and the like according to the roles thereof.
The casing part 1100 includes casings 1110 and a thermal expansion absorbing member 1120. The casing part 1100 includes at least two casings 1110 separated from each other, and the casings 1110 separated from each other may be connected by the mediation of the thermal expansion absorbing member 1120 capable of absorbing deformation due to thermal expansion.
One side of the casing 1100 may be provided with a gas inlet 1100a through which the exhaust gas of a gas turbine (not shown) is introduced, and an opposite side may be provided with a gas outlet 1100b for discharging the exhaust gas into the atmosphere.
The casing 1110 may be provided in a metallic material, thereby being able to be thermally expanded by high-temperature exhaust gas, and the thermal expansion absorbing member 1120 is configured to have fluidity in order to mitigate the thermal expansion of the casings 1110 separated from each other.
With reference to
The header 1310 stores the fluid that flows through the connection tube 1210 of the connection tube unit 1200. It is connected to one end of the connection tube 1210, providing support for that one end of the connection tube 1210. The header 1310 may be installed on an inner wall surface of the casing part 1100.
The tube sheet 1320 supports a plurality of connection tubes 1210, with their one ends connected to the header 1310. The tube sheet 1320 is designed to have the plurality of connection tubes 1210 pass through it, and it is provided with a plurality of support holes 1321. These support holes 1321 are specifically positioned to support circumferential surfaces of the plurality of connection tubes 1210 as they pass through the tube sheet 1320. The plurality of support holes 1321 provided in the tube sheet 1320 supports circumferential surfaces of the plurality of connection tubes 1210, respectively, and a plurality of tube sheets 1320 is installed to be spaced apart from each other in a longitudinal direction of the plurality of connection tubes 1210. Each of the plurality of tube sheets 1320 may be generally in a form of a flat plane, disposed parallel to the upper and the lower directions.
With reference to
When the length L of the support hole 1321 is longer than the outer diameter D of the connection tube 1210 by greater than 1.7 times, an impact caused by the flow of the tube sheet 1320 may be transferred to the connection tube 1210, and the connection tube 1210 may be damaged. In the case in which the length L of the support hole 1321 is equal to the outer diameter of the connection tube 1210, when the tube sheet 1320 flows due to thermal expansion, a problem that can occur is that the connection tube 1210 flows together.
With reference to
For example, when the tube sheet 1320 pertains to a condition of moving in an upper direction according to the thermal expansion analysis, the connection tube 1210 may be positioned on an upper side part of the support hole 1321 (see
When the connection tube 1210 is inserted to be positioned on the upper side part of the support hole 1321 provided in the tube sheet 1320 before the thermal expansion, a space is secured at a lower part of the support hole 1321. This arrangement helps eliminate any potential constraints that may occur when the tube sheet 1320 and the support holes 1321 therein moves upward during thermal expansion.
When the tube sheet 1320 pertains to a condition of moving in a lower direction according to the thermal expansion analysis, the connection tube 1210 may be positioned on a lower side part of the support hole 1321 (see
When the connection tube 1210 is inserted to be positioned on the lower side part of the support hole 1321 provided in the tube sheet 1320 before the thermal expansion, a space is secured at the upper part of the support hole 1321 This arrangement helps eliminate any potential constraints that may occur when the tube sheet 1320 and the support holes 1321 therein moves downward during thermal expansion.
When the tube sheet 1320 pertains to a condition of moving in the upper and lower directions according to the thermal expansion analysis, the connection tube 1210 may be positioned in a central part of the support hole 1321 (see
In this case, a space is secured at both of upper and lower parts of the support hole 1321, whereby constraining conditions may be removed that may occur during thermal expansion.
With reference to
Furthermore, when the third row is adjacent to the second row, the plurality of support holes 1321 in the third row is positioned on the same line as the plurality of support holes 1321 in the first row in the vertical direction, and when the fourth row is adjacent to the third row, a plurality of support holes 1321 in a fourth row is positioned on the same line as the plurality of support holes 1321 in the second row in the vertical direction.
Out of the plurality of support holes 1321 disposed in the plurality of rows in the tube sheet 1320, a plurality of odd-numbered support holes 1321 is positioned on the same line in the vertical direction, and a plurality of even-numbered rows of support holes 1321 is positioned between and in the middle of the odd-numbered rows of support holes 1321, whereby on the tube sheet 1320, the plurality of odd-numbered and even-numbered support holes 1321 is arranged in a zigzag shape. As a result of this arrangement, smooth heat exchange occurs between the exhaust gas flowing into the casing part 1100 and the fluid moving through the plurality of connection tubes 1210. The positioning and spacing of the support holes in the tube sheet 1320 allow for efficient and effective heat exchange between the two mediums.
Furthermore, the long hole-shaped support holes 1321 provided in the tube sheet 1320 enables stable support of the connection tube 1210 while maintain flexibility to accommodate the thermal expansion-induced motion of the connection tube 1210 and the tube sheet 1320. This design feature allows the connection tube 1210, through which heat-exchanging fluid flow and exchanges heat with exhaust gas, to be effectively supported and ensure its motion is accommodated without compromising stability.
Although the present disclosure has been described with reference to the embodiments shown in the drawings, this is only exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present disclosure should be determined by the spirit of the technical writings of the appended claims.
Number | Date | Country | Kind |
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10-2022-0162829 | Nov 2022 | KR | national |