The present invention relates to a tube expansion method of fixing a heat exchanger tube inserted to a tube hole of a tubesheet to the tube hole by expanding the heat exchanger tube from inside.
Conventionally, for example, in a tube expansion method described in Patent Literature 1, a tube expansion method of fixing the heat exchanger tube to the tubesheet of a heat exchanger of a steam generator or the like has been disclosed. In such a tube expansion method, as a first step, each end portion of the corresponding heat exchanger tube is inserted into the tube hole passing through the tubesheet in a plate thickness direction, and each end portion of the heat exchanger tube inserted into the tube hole is subjected to a roller tube expansion in a range of a predetermined distance toward an end surface of a secondary side from an end surface of a primary side of the tubesheet. Next, as a second step, in order to block a gap between an outer circumferential surface of the expanded heat exchanger tube and an inner circumferential surface of the tube hole, seal welding is performed on the end surface of the primary side of the tubesheet along the outer circumferential surface of the heat exchanger tube and the inner circumferential surface of the tube hole. Next, as a third step, each end portion of the heat exchanger tube inserted into the tube hole is subjected to a hydraulic tube expansion in the range of a predetermined distance toward the end surface of the primary side from the end surface of the secondary side of the tubesheet. Next, as a fourth step, each end portion of the heat exchanger tube inserted into the tube hole is subjected to the roller tube expansion in a range of not being expanded yet in the first step and the third step, and the entire outer circumferential surface of each end portion of the heat exchanger tube inserted into the tube hole is brought into close contact with the inner circumferential surface of the tube hole.
Patent Literature 1: Japanese Patent Application Laid-open No. 2008-025918
Incidentally, since the tube hole of the tubesheet is formed by a drill, in some cases, there is damage along the circumferential direction with respect to the inner circumferential surface in the middle of the axial direction of the tube hole, by chips being rarely caught by the drill. In this case, when performing the tube expansion by the above-described conventional tube expansion method, a recessed portion may be formed on the inner circumferential surface of the heat exchanger tube expanded by the hydraulic tube expansion of the third step, by being expanded along the damage. For this reason, there is a problem in that residual stress may be locally generated at a position of the recessed portion, or stress concentration may occur due to thermal expansion during operation of the heat exchanger.
The present invention has been made to solve the above-described problems, and an object thereof is to provide a tube expansion method capable of preventing a situation in which a recessed portion is formed on the inner circumferential surface of the heat exchanger tube, when there is damage along the circumferential direction with respect to the inner circumferential surface in the middle of the axial direction of the tube hole.
According to an aspect of the present invention in order to achieve the object, there is provided a tube expansion method of fixing a heat exchanger tube inserted to a tube hole of a tubesheet by tube expansion, the method including: when there is a damage along a circumferential direction with respect to an inner circumferential surface in the middle of an axial direction of the tube hole, a first hydraulic tube expansion step of performing a hydraulic tube expansion in a range including the damage at a pressure of 15% to 70%; and a second hydraulic tube expansion step of performing the hydraulic tube expansion in each range divided except the damage at a pressure of 100%.
According to the tube expansion method, by initially performing a first hydraulic tube expansion step, the outer circumferential surface of the heat exchanger tube is expanded in advance to fit the inner circumferential surface of the tube hole in the range including the damage. Moreover, by subsequently performing a second hydraulic tube expansion step, each range divided except the damage is subjected to the main tube expansion, and the heat exchanger tube has a uniform inner diameter even at a position of the damage, while the outer circumferential surface of the heat exchanger tube comes into close contact with the inner circumferential surface of the tube hole. As a result, when the inner circumferential surface in the middle of the axial direction of the tube hole is damaged along the circumferential direction, it is possible to prevent a situation in which the recessed portion is formed on the inner circumferential surface of the heat exchanger tube.
According to an another aspect of the present invention, there is provided a tube expansion method of fixing a heat exchanger tube inserted to a tube hole of a tubesheet by tube expansion, the method including: when there is a damage along a circumferential direction with respect to an inner circumferential surface in the middle of an axial direction of the tube hole, a first roller tube expansion step of performing a roller tube expansion in a range A of a predetermined distance that does not reach the damage toward an end surface of the other side from an end surface of one side of the tubesheet in which the end portion of the heat exchanger tube is located; a first hydraulic tube expansion step of performing a hydraulic tube expansion at a pressure of 15% to 70% in a range B including the damage as a range that is except the range of A and a predetermined distance toward the end surface of one side from the end surface of the other side of the tubesheet; a second hydraulic tube expansion step of performing each hydraulic tube expansion at a pressure of 100% in each range C divided from the range B except the damage; and a second roller tube expansion step of performing the roller tube expansion in a range D that is not expanded yet between the range A and the range B.
According to the tube expansion method, by initially performing the first hydraulic tube expansion step on the hydraulic tube expansion, the outer circumferential surface of the heat exchanger tube is expanded in advance to fit the inner circumferential surface of the tube hole in the range B including the damage. Moreover, by subsequently performing the second hydraulic tube expansion step, each range C divided except the damage is subjected to the main tube expansion, and the heat exchanger tube has the uniform inner diameter even at a position of the damage, while the outer circumferential surface of the heat exchanger tube comes into close contact with the inner circumferential surface of the tube hole.
As a result, when the inner circumferential surface in the middle of the axial direction of the tube hole is damaged along the circumferential direction, it is possible to prevent a situation in which the recessed portion is formed on the inner circumferential surface of the heat exchanger tube. In addition, by bringing the end portion of the heat exchanger tube into close contact with the tube hole by the first roller tube expansion step, by subsequently performing each hydraulic tube expansion step, and thereafter, by expanding a boundary between the first roller tube expansion step and each hydraulic tube expansion step by the second roller tube expansion step, it is possible to perform high-precision tube expansion by positioning the end portion of the heat exchanger tube.
According to the present invention, when the inner circumferential surface in the middle of the axial direction of the tube hole is damaged along the circumferential direction, it is possible to prevent a situation in which the recessed portion is formed on the inner circumferential surface of the heat exchanger tube.
An embodiment according to the present invention will be described below in detail with reference to the drawings. It is not intended that the invention be limited by the embodiment. Furthermore, components in the embodiment described below include components that are easily replaceable by those skilled in the art or substantially the same components.
As illustrated in
A channel head 107 is joined to a lower end portion of the body portion 102. The interior of the channel head 107 is divided into an inlet side water chamber 107A and an outlet side water chamber 107B by a partition plate 108, in a state in which an opening edge formed in a bowl shape is joined to the tubesheet 104. The inlet side water chamber 107A is in communication with one end portion of each heat exchanger tube 105, and the outlet side water chamber 107B is in communication with the other end portion of each heat exchanger tube 105. Furthermore, the inlet side water chamber 107A is formed with an inlet side tube base 107Aa leading to the outside of the body portion 102, and the outlet side water chamber 107B is formed with an outlet side tube base 107Ba leading to the outside of the body portion 102. Moreover, the inlet side tube base 107Aa is connected to a cooling water tube 124 (see
Furthermore, in the upper half portion of the body portion 102, a gas-water separator 109 that separates the water supply into steam and hot water, and a moisture separator 110 that removes the moisture of the separated steam to provide a state close to the dry steam are provided. A water supply tube 111 is inserted between the gas-water separator 109 and the heat exchanger tube group 105A, and the water supply tube 111 performs the water supply of the secondary cooling water into the body portion 102 from the outside. Further, at the upper end portion, the body portion 102 is formed with a steam discharge port 112. Further, in the lower half portion, the body portion 102 is formed with a water supply path 113 that allows the secondary cooling water supplied into the body portion 102 from the water supply tube 111 to flow down between the body portion 102 and the tube bundle shroud 103, return back by the tubesheet 104, and rise along the heat exchanger tube group 105A. In addition, the steam discharge port 112 is connected to a cooling water piping (not illustrated) that sends steam to a turbine, and the water supply tube 111 is connected to a cooling water piping (not illustrated) for supplying the secondary cooling water in which steam used in the turbine is cooled in a condenser (not illustrated).
As illustrated in
The reactor vessel 121 is formed by a vessel main body 121a and a vessel lid 121b mounted thereon so that a fuel assembly (not illustrated) can be inserted and removed. The vessel lid 121b is provided to be able to open and close with respect to the vessel main body 121a. The vessel main body 121a forms a cylindrical shape in which the upper part thereof opens and the lower part thereof is closed in a hemispherical shape, and an inlet side tube base 121c and an outlet side tube base 121d that supply and discharge the light water as the primary cooling water are provided at the top thereof. The outlet side tube base 121d is connected to the cooling water tube 124 so as to communicate with the inlet side tube base 107Aa of the steam generator 101. Further, the inlet side tube base 121c is connected the cooling water tube 124 so as to communicate with the outlet side tube base 107Ba of the steam generator 101.
In the nuclear power apparatus 120, the primary cooling water is heated by the reactor vessel 121 to enter a high-pressure and high-temperature state, and the primary cooling water is supplied to the steam generator 101 via the cooling water tube 124, while being maintained at a constant pressure by being pressurized by the pressurizer 122. In the steam generator 101, the heated primary cooling water is sent to the inlet side water chamber 107A, circulates through the large number of heat exchanger tubes 105, and reaches the outlet side water chamber 107B. Meanwhile, the secondary cooling water cooled by the condenser is sent to the water supply tube 111, and rises along the heat exchanger tube group 105A through a water supply path 113 of the body portion 102. At this time, within the body portion 102, heat is exchanged between the high-pressure and high-temperature primary cooling water and the secondary cooling water. Moreover, the cooled primary cooling water is returned to the pressurized water reactor from the outlet side water chamber 107B. Meanwhile, the secondary cooling water subjected to heat exchange with the high-pressure and high-temperature primary cooling water rises in the body portion 102, and is separated into the steam and the hot water in the gas-water separator 109. The separated steam is sent to the turbine from the steam discharge port 112 after the moisture is removed by the moisture separator 110. The turbine is driven by steam of the secondary cooling water. Moreover, the power of the turbine is transmitted to a generator (not illustrated) to generate electricity. The steam supplied to driving of the turbine is supplied to the steam generator 101, by being condensed and converted into water. Meanwhile, the primary cooling water after the heat exchange in the steam generator 101 is collected to the pump 123 side via the cooling water tube 124.
Concerning the above-described steam generator 101, the heat exchanger tube 105 is mounted to the upper half portion of the body portion 102, or to the lower half portion of the body portion 102 before the gas-water separator 109, the moisture separator 110, and the water supply tube 111 provided on the upper half portion are disposed. In this case, the tube bundle shroud 103, the tubesheet 104, and each tube support plate 106 are mounted to the lower half portion of the body portion 102, in a state of being laterally placed on a pedestal (not illustrated). The tubesheet 104 and the tube support plate 106 are provided with tube holes 104a and 106a for inserting the end portions of the heat exchanger tubes 105 therein.
The heat exchanger tube 105 is mounted to the lower half portion of the body portion 102. From the lower half portion and the upper half portion (upper side of FIG. 6) of the body portion 102, both end portions of the heat exchanger tube 105 are inserted into the tube hole 106a of the tube support plate 106, and are inserted into the tube hole 104a of the tubesheet 104 such that the circular arc portion formed in a U shape is disposed in a hemispherical shape on the upper side in the lower half portion of the body portion 102.
The heat exchanger tubes 105 inserted into the tube holes 106a and 104a of the tube support plate 106 and the tubesheet 104 are based on a heat exchanger tube of one layer formed by horizontally arranging a plurality of tubes so that the smallest-diameter circular arc portion formed in a U shape is located at the center and the gradually large-diameter circular arc portion is located outward therefrom. Moreover, the vibration suppression member 105a is disposed at a predetermined position between each heat exchanger tube layer, while stacking the heat exchanger tube layers. As a result, a portion of the circular arc portion of the heat exchanger tube 105 is formed in a hemispherical shape.
Thus, the above-described problem is solved by expanding the heat exchanger tube 105 using the tube expansion method of this embodiment.
First, as illustrated in
Next, as illustrated in
As illustrated in
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Next, as illustrated in
As illustrated in
The liquid introduction portion 12 is a portion into which the liquid is introduced from a liquid supply device (not illustrated), and is also a coupling portion that is inserted into the liquid supply portion of the liquid supply device. For this reason, an O-ring 14 is provided on the outer circumferential surface of the liquid introduction portion 12 to prevent liquid leakage from between the liquid supply portion and the liquid introduction portion 12.
The mandrel portion 13 has a first cylindrical portion 13A disposed in the middle, and a second cylindrical portion 13B and a third cylindrical portion 13C that extend toward the axis S2 direction from both ends of the first cylindrical portion 13A, respectively. The first cylindrical portion 13A is formed to have a larger outer diameter than those of the second cylindrical portion 13B and the third cylindrical portion 13C. The second cylindrical portion 13B is connected to the base portion 11, and the third cylindrical portion 13C is provided on the opposite side of the base portion 11 in the axis S2 direction.
Moreover, through holes 12a, 11a, and 13a are continuously formed to lead to the middle of the first cylindrical portion 13A from the liquid introduction portion 12 via the base portion 11 and the second cylindrical portion 13B in the axis S2 direction. The through hole 13a extends in a direction intersecting with the axis S2 at the position of the first cylindrical portion 13A and penetrates the side portion of the first cylindrical portion 13A.
In the mandrel portion 13, O-rings 15 and 16 are inserted into the second cylindrical portion 13B and the third cylindrical portion 13C to be movable in the axis S2 direction, respectively. The O-rings 15 and 16 abut against the first cylindrical portion 13A to restrict the movement. The O-rings 15 and 16 have a size to come into contact with the outer circumferential surfaces of the second cylindrical portion 13B and the third cylindrical portion 13C, and the inner circumferential surface of the unexpanded heat exchanger tube 105. Further, in the second cylindrical portion 13B and the third cylindrical portion 13C, annular guide members 17 and 18 are inserted to the outer side in the axis S2 direction of each of the O-rings 15 and 16 centered at the first cylindrical portion 13A to be movable in the axis S2 direction. Further, in the second cylindrical portion 13B and the third cylindrical portion 13C, annular deformation members 19 and 20 are inserted to the outer side of each of the annular guide members 17 and 18 centered at the first cylindrical portion 13A to be movable in the axis S2 direction. Further, in the second cylindrical portion 13B and the third cylindrical portion 13C, annular locking members 21 and 22 are fixed to the outer side of each of the annular deformation members 19 and 20 centered at the first cylindrical portion 13A. Further, annular positioning members 23 and 24 are disposed on the outer circumferential surfaces of the annular locking members 21 and 22. The annular positioning members 23 and 24 are shaped so that the outer diameters thereof have substantially the same size as the inner diameter of the unexpanded heat exchanger tube 105.
As illustrated in
The hydraulic tube expander 1 determines the distance in the axis S2 direction that can be expanded depending on the distance in the axis S2 direction of the annular locking members 21 and 22. That is, the above-described ranges B and C of the hydraulic tube expansion can be set by changing the distance in the axis S2 direction of the annular locking members 21 and 22 of the hydraulic tube expander 1.
Next, referring back to
In this way, the tube expansion method of the embodiment includes, when there is groove 104b along the circumferential direction on the inner circumferential surface in the middle of the axis S1 direction of the tube hole 104a, a first hydraulic tube expansion step of performing the hydraulic tube expansion in the range B including the groove 104b at a pressure of 15% to 70%, and thereafter, a second hydraulic tube expansion step of performing the hydraulic tube expansion in each range C divided except the groove 104b at a pressure of 100%.
According to the tube expansion method, by initially performing the first hydraulic tube expansion step, in the range B including the groove 104b, the tube expansion is performed in advance so that the outer circumferential surface of the heat exchanger tube 105 fits to the inner circumferential surface of the tube hole 104a. Moreover, by subsequently performing the second hydraulic tube expansion step, each range C divided except the groove 104b is subjected to the main tube expansion, and the heat exchanger tube 105 has a uniform inner diameter even at the position of the groove 104b, while the outer circumferential surface of the heat exchanger tube 105 comes into close contact with the inner circumferential surface of the tube hole 104a. As a result, when there is groove 104b along the circumferential direction on the inner circumferential surface in the middle of the axis S1 direction of the tube hole 104a, it is possible prevent a situation in which the recessed portion 105d is formed on the inner circumferential surface of the heat exchanger tube 105.
Further, the tube expansion method of this embodiment includes, when there is groove 104b along the circumferential direction on the inner circumferential surface in the middle of the axis S1 direction of the tube hole 104a, a first roller tube expansion step of performing the roller tube expansion in the range A of a predetermined distance that does not reach the groove 104b toward the end surface of the secondary side (the other side) from the end surface of the primary side (one side) of the tubesheet 104 in which the end portion of the heat exchanger tube 105 is positioned, thereafter, the first hydraulic tube expansion step of performing the hydraulic tube expansion at a pressure of 15% to 70% in the range B including the groove 104b as a range of a predetermined distance toward the end surface of one side from end surface of the other side of the tubesheet 104 except the range of A, thereafter, a second hydraulic tube expansion step of performing each hydraulic tube expansion at a pressure of 100% in each range C divided from the range B except the groove 104b, and thereafter, a second roller tube expansion step of performing the roller tube expansion in the range D that is not expanded yet between the range A and the range B.
According to the tube expansion method, regarding the hydraulic tube expansion, by initially performing the first hydraulic tube expansion step, the tube expansion is performed in advance so that the outer circumferential surface of the heat exchanger tube 105 fits to the inner circumferential surface of the tube hole 104a in the range B including the groove 104b. Moreover, by subsequently performing the second hydraulic tube expansion step, each range C divided except the groove 104b is subjected to the main tube expansion, and the heat exchanger tube 105 has the uniform inner diameter even at the position of the groove 104b, while the outer circumferential surface of the heat exchanger tube 105 comes into close contact with the inner circumferential surface of the tube hole 104a. As a result, when there is groove 104b along the circumferential direction on the inner circumferential surface in the middle of the axis S1 direction of the tube hole 104a, it is possible to prevent a situation in which the recessed portion 105d is formed on the inner circumferential surface of the heat exchanger tube 105. In addition, by bringing the end portion of the heat exchanger tube 105 into close contact with the tube hole 104a by the first roller tube expansion step, by subsequently performing the hydraulic tube expansion step, and by subsequently expanding the boundary between the first roller tube expansion step and each hydraulic tube expansion step by the second roller tube expansion step, it is possible to perform the high-precision tube expansion by positioning the end portion of the heat exchanger tube 105.
1 HYDRAULIC TUBE EXPANDER
2 ROLLER TUBE EXPANDER
104 TUBESHEET
104
a TUBE HOLE
104
b GROOVE
104
c END SURFACE OF PRIMARY SIDE (ONE SIDE)
104
d END SURFACE OF SECONDARY SIDE (THE OTHER SIDE)
105 HEAT EXCHANGER TUBE
S1 AXIS
Number | Date | Country | Kind |
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2012-077915 | Mar 2012 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2012/080783 | 11/28/2012 | WO | 00 |