JP4772654B2 - Replacement method for internal structure of moisture separator - Google Patents

Description

  The present invention relates to a moisture separator used in a power plant of a nuclear power plant, and in particular, by disposing steam distribution moisture in the moisture separator, the steam introduced into the moisture separator The present invention relates to a replacement method for a moisture separator internal structure that can efficiently and vertically divert to a separation element to make the flow of steam uniform.

In boiling water nuclear power plants, steam generated in a nuclear reactor is sent to a turbine to rotate the turbine, and a generator directly connected to the turbine is driven to generate power.
FIG. 9 schematically shows the arrangement of equipment such as turbines in a turbine building in a nuclear power plant.
In FIG. 9, the turbine is configured by connecting a high-pressure turbine 1 and a low-pressure turbine 2, and a moisture separator 3 is installed between the high-pressure turbine 1 and the low-pressure turbine 2. The moisture separator 3 removes moisture in the steam to make dry steam. The steam that has rotated the high-pressure turbine 1 is introduced into the moisture separator 3 so that the moisture is removed and then supplied to the low-pressure turbine 2. A plurality of low-pressure turbines 2 are installed, and each low-pressure turbine 2 is supplied with dry steam from a moisture separator similar to the moisture separator 3. The steam that has finished work in the low-pressure turbine 2 is condensed in the condenser 4 to become condensate.

  The high-pressure turbine 1 and the low-pressure turbine 2 are installed on a turbine base 5. In addition, a suspension support 7 is suspended from the turbine base 5, and this suspension support 7 is connected to a suspension fitting 6 attached to the outer peripheral surface of the moisture separator 3, whereby the moisture separator 3 is It is supported by the suspension support 7.

  FIG. 10 is a plan view schematically showing the arrangement of the wet separator 3 in FIG. As shown in FIG. 10, moisture separators 3a, 3b, 3c, and 3d are also arranged around the moisture separator 3 of FIG.

  Next, FIGS. 11 and 12 show the internal structure of the moisture separator 3.

  The moisture separator 3 constitutes a container from a vertically long trunk body 8 and a pair of end plates 10 that closes both ends of the trunk body 8, and a plurality of moisture separation elements 9 are accommodated therein. . This moisture separation element 9 is divided into upper and lower parts and attached to upper and lower partition plates 21 respectively.

  Inside the moisture separator 3, a chamber in which the moisture separation element 9 is accommodated is defined by the upper and lower partition plates 21, the porous plate 17, and the guide vanes 12. The wet steam flowing in from the steam input account 13 is diverted by the sorase plate 11, the perforated plate 17, and the guide vane 12 and guided to the moisture separation element 9. The dry steam from which moisture has been removed through the moisture separation element 9 is led from the steam outlet 13 to the low pressure turbine 2. On the other hand, the moisture separated by the moisture separation element 9 is collected to form a drain and is discharged from the drain reservoir 20 through the drain pipe 20 to the outside.

  As a result of long-term operation of nuclear power generation facilities, the moisture separator is regularly inspected to prevent performance degradation due to aging. As a result, necessary repairs are performed as needed. For example, replacement work is often performed on degraded moisture separation elements.

  In the case of a moisture separator, in particular, the internal structure of the moisture separator has deteriorated over time due to the influence of the internal fluid due to the long-term operation of the power plant. In fact, in many cases, damage to internal structures is observed when opening conversion is performed during regular inspections. Damaged parts are repaired as much as possible by applying a contact plate, welding, and overlaying. Such conventional repairs are limited to emergency measures.

On the other hand, with the increased output of nuclear power plants, there is a need to increase the capacity of the existing moisture separator.
In order to cope with this, a set of replacement methods in which an existing moisture separator is replaced with a larger-capacity moisture separator has been studied.

  However, a lot of equipment is installed in the turbine building where the moisture separator is placed, and a wide variety of pipes are installed around it. It is very difficult to secure a route for carrying in a new moisture separator in place of the vessel, and so far, a complete replacement of the moisture separator has been realized.

  Accordingly, an object of the present invention is to solve the problems of the prior art and to realize the ability of the moisture separator to be improved simultaneously with the replacement of the moisture separation element without using the set replacement method. An object of the present invention is to provide a replacement method for the internal structure of the moisture separator.

In order to achieve the above-mentioned object, the invention of claim 1 is to remove a deteriorated moisture separation element that is divided in the longitudinal direction inside a moisture separator body installed in a power plant of a nuclear power plant. A method of replacing with a new one, removing the deteriorated moisture separation element from the inside of the body of the moisture separator, installing a new moisture separation element, and the newly replaced moisture separation element and the moisture separation. A steam distribution chamber having a grid-like panel parallel to the moisture separation element is installed between the steam inlet account of the vessel body, and between the moisture separator element and the steam outlet account of the moisture separator body. An outlet porous chamber is installed by a perforated panel that is partitioned to form a large number of holes, and the grid-like panel and the perforated panel forming the vapor distribution chamber and the outlet porous chamber are formed in the moisture separator. Has been a carry-capable split consists manhole, is characterized in that a uniform flow of steam into the moisture separating element.

  In the first aspect of the present invention, it is preferable that an outlet perforated chamber partitioned by a perforated plate having a plurality of holes for narrowing the flow of steam is additionally installed between the moisture separation element and the steam outlet account.

  Further, in the invention of claim 1, the panel partitioning the vapor distribution chamber, the moisture separation element, and the porous porous plate of the outlet porous are divided into sizes that can be carried from the manhole of the moisture separator body. It is preferable to have a panel structure.

  According to the first aspect of the present invention, the steam flow rate is increased by the existing solar plate or guide vane by additionally installing the steam distribution chamber between the steam inlet account and the moisture separation element without using the set replacement method. Improperly improve the situation where the steam flow was not evenly distributed over the entire surface of the moisture separation element, resulting in an inefficient steam flow, decelerate to an appropriate flow rate and spread evenly in front of the moisture separation element Can do.

  In the first aspect of the present invention, when the outlet porous chamber is provided between the steam separation element and the steam outlet chamber, a pressure difference occurs between the inside and outside of the outlet porous chamber. The steam flow is easily drawn into the separation element, and the function of the steam distribution chamber is promoted to make the steam flow more uniform and dispersed. As a result, the capacity of the moisture separator can be increased not only by simply replacing the moisture separation element and restoring the capacity of the moisture separation element, but also by responding to the increased output of the power generation equipment of the nuclear power plant. it can.

  According to the invention of claim 1, it is possible to carry in and assemble the materials of the moisture separation element, the steam branch chamber and the outlet porous chamber into the moisture separator 3, and the additional installation becomes easy.

Hereinafter, an embodiment of a moisture separator internal structure replacement method according to the present invention will be described with reference to the accompanying drawings.
The replacement method according to the present embodiment will be described using the moisture separator shown in FIG. 11 as an example.
The moisture separator 3 is a vertical type separator, and a container is constituted by a vertically long trunk body 8 and a pair of end plates 10 that close both ends of the trunk body 8. A plurality of moisture separation elements 9 are accommodated in the separator. The moisture separation element 9 is divided and arranged in the vertical direction, and is attached to the upper and lower partition plates 21 and 21, respectively.

  Inside the moisture separator 3, the upper and lower partition plates 21, 21, the perforated plate 17, and the guide vanes 12 define a chamber in which the moisture separation element 9 is accommodated. The wet steam flowing in from the steam input account 13 is diverted by the sorase plate 11, the perforated plate 17, and the guide vane 12 and guided to the moisture separation element 9. Dry steam from which moisture has been removed through the moisture separation element 9 is led from the steam outlet 14 to the low-pressure turbine 2. On the other hand, the moisture separated by the moisture separation element 9 is collected to form a drain and is discharged from the drain reservoir 20 through the drain pipe 20 to the outside.

In such a moisture separator 3, the moisture separation element 9 deteriorates over time due to long-term operation of the nuclear power plant.
In the old type moisture separator 3, the steam flow is divided and sent to each moisture separation element 9 which is divided vertically by the sorase plate 11 and the guide vane 12. Since the speed is not appropriate, there is a case where the steam flow does not spread over the entire surface of the moisture separation element 9 and the flow is inefficient. In such an old type moisture separator 3, the capacity can be recovered only by replacing the deteriorated moisture separation element 9 with a new one, and the capacity cannot be increased.
On the other hand, it is necessary to increase the capacity of the moisture separator 3 in conjunction with the replacement of the moisture separation element 9 so that the output of the power generation equipment of the nuclear power plant can be accommodated.
Therefore, in the present embodiment, the following replacement method is performed.

  First, in the moisture separator 3 shown in FIG. 11, the existing moisture separation element 9 deteriorated from the moisture separator 3 is removed, and a new moisture separation element 9 is installed. At this time, the difference between the existing moisture separation element 9 and the new moisture separation element 9 is that not only the latter is new, but also a single moisture separation element 9 is composed of a panel divided into a plurality of parts. Is where you are. Each panel has a size that can be carried into the manhole 16 of the moisture separator 3, and is assembled with bolts, nuts, and the like inside the carried moisture separator 3.

  In conjunction with the replacement work of the moisture separation element 9, the existing solace plate 11, perforated plate 17, and guide vane 12 are removed, disassembled into a size that can be carried out, and removed from the moisture separator 3.

  Next, FIG. 1 shows that the moisture separation element 9 is replaced and the separator plate 11, the guide vane 12 and the like are removed, and the moisture separation chamber 22 and the outlet porous chamber 23 (see FIG. 2) are additionally installed. A container 3 is shown.

  The steam distribution chamber 22 is installed between the newly replaced moisture separation element 9 and the steam inlet account 13 of the moisture separator 3 main body. The steam introduced into the steam distribution chamber 22 from the steam inlet account 13 flows from the lattice panel 30 toward the moisture separation element 9.

  The lattice panel 30 is a panel partitioned in a lattice shape in order to make the flow of steam to the moisture separation element 9 uniform. As shown in FIG. 3, this lattice panel 30 is a combination of plate materials and joined using bolts 31 and nuts 32 to form a single lattice-like panel. Therefore, the lattice panel 30 can be assembled into the moisture separator 3 by loading the constituting plate material from the manhole 16. Of the panels that partition the vapor distribution chamber 22, the side panel 33 is not a grid-like panel, but is a split-type panel.

The lattice panel 30 is installed in parallel to the moisture separation element 9, and the size of each lattice is such that the steam is decelerated to an appropriate flow rate and flows uniformly over the entire surface of the moisture separation element 9. To be set.
Next, in FIG. 1 and FIG. 2, the outlet porous chamber 23 is partitioned between the moisture separation element 9 and the vapor outlet account 14. In this embodiment, the exit porous chamber 23 is partitioned using a perforated plate 34 that is curved in a kamaboko shape. The perforated plate 34 has many holes for narrowing the flow of steam. The perforated plate 34 is also divided into a plurality of panels, and each panel can be loaded from the manhole 16 and assembled inside the moisture separator 3.

  As described above, the following effects can be obtained by additionally installing the vapor distribution chamber 22 and the outlet porous chamber 23 in association with the replacement of the moisture separation element 9 that has deteriorated over time with a new one.

  First, the steam distribution chamber 22 is additionally installed between the steam inlet account 13 and the moisture separation element 9, so that the steam flow rate is not appropriate due to the existing plate 11 and the guide vanes 12, and the entire surface of the moisture separation element 9. It is possible to improve the situation where the steam flow is not evenly distributed and the steam flow is inefficient. That is, the steam introduced into the steam distribution chamber 22 is decelerated to an appropriate flow rate through the lattice of the lattice panel 30 and can be evenly diffused in front of the moisture separation element 9. In this embodiment, the lattice panel 30 is used, but it may be constituted by a perforated plate in which holes having appropriate hole diameters are arranged in a staggered shape or a lattice shape.

  Further, by additionally installing the outlet porous chamber 23, a pressure difference is generated inside and outside the outlet porous chamber 23. That is, since steam is squeezed when it flows through the hole of the outlet porous chamber 23 and expands in the outlet porous chamber 23, the inside of the outlet porous chamber 23 has a lower pressure. This pressure difference makes it easier for the steam flow to be drawn from the steam diversion chamber 22 to the moisture separation element 9, and the function of the vapor diversion chamber 22 is promoted to make the vapor flow more uniform and dispersed.

  In this way, the moisture separation element 9 can be replaced with a new one without replacing the set, and the vapor distribution chamber 22 and the outlet porous chamber 23 can be additionally installed. The capacity of the moisture separator 3 can be increased not only to restore the capacity of the moisture separation element but also to increase the output of the power generation equipment of the nuclear power plant.

  Since the moisture separation element 9, the vapor distribution chamber 22, and the outlet porous chamber 23 have a divided panel structure, it is possible to carry the material into the moisture separator 3 for assembly, and additional installation is possible. Easy. In addition, even if it becomes necessary to cope with the increased output of the power generation facility after these are installed additionally, it has a split panel structure, so it can be accommodated by adding more panels according to the increased output. Is possible.

  In the embodiment described above, the material is carried in and out of the manhole 16 without changing the body of the moisture separator 3 such as cutting, the moisture separation element is replaced, the vapor distribution chamber 22 and the outlet perforation. Although an example in which the chamber 23 is additionally installed has been described, in FIG. 11, a material such as a panel may be carried in by cutting the end plate 10 from the trunk body 8 or providing a window frame on the trunk body 8. Good.

  The embodiment described above replaces the moisture separation element 9 in the internal structure of the moisture separator 3 in FIG. 11 and then replaces the existing solar plate 11 and the guide vane 12 with a steam distribution chamber. 22 is additionally installed.

  On the other hand, in all of the embodiments shown in FIGS. 4 to 6, it is common to replace the moisture separation element 9 that has deteriorated over time with a new one, but in conjunction with the replacement of the moisture separation element 9. In this embodiment, the existing sheet plate 11, guide vane 12, or newly replaced moisture separation element 9 is modified.

First, FIG. 4 shows the renovation performed on the sorase board 11 after the moisture separation element 9 that has deteriorated over time is replaced with a new one.
In FIG. 4, assuming that the angle formed by the pair of the existing surface plate 11 is θ ′, after replacing the moisture separation element 9, the surface plate 11 is repaired so that the inclination becomes an inclination indicated by a virtual line. . The angle of the flat plate 11 at this time is more obtuse than the angle θ before the repair.

  Thus, by making the angle θ formed by the pair of the sorase plates 11 more obtuse, the inclination of each of the sorase plates 11 can be further smoothed. This makes it possible to make the steam flow to the moisture separation element 9 more uniform and disperse when the flow of steam that has flowed horizontally from the steam input account 13 is collided with the solar plate 11 and changed. The separation efficiency by the moisture separation element 9 after the replacement can be further increased.

Next, FIG. 5 shows a modification performed on the guide vane 12 after the aged moisture separation element 9 is replaced with a new one.
In FIG. 5, L indicates the length of the guide vane 12 after the repair. The length L of the guide vane 12 is longer than that before the repair.

  Such a modification of the guide vane 12 makes it possible to improve the angle and direction of the steam flow flowing along the guide vane 12 in a direction in which the steam flow to the moisture separation element 9 is made more uniform and dispersed. The separation efficiency by the moisture separation element 9 after the replacement can be further increased.

  Next, FIG. 6 shows an embodiment in which the orientation of the new moisture separation element is modified to be perpendicular to the steam flow changed by the sorase plate and guide vanes.

  As can be seen by comparing this FIG. 6 with the diagram showing the moisture separator 3 before the modification, the steam is perpendicular to the moisture separation element 9 after the modification. Separation efficiency can be further increased.

  In the above, the replacement method of the internal structure in the single moisture separator has been described with reference to FIGS. 1 to 6. Next, with reference to FIGS. A method for replacing the internal structure with a set of separators and renovating the moisture separator into one moisture separator will be described.

First, FIG. 7 (a) to FIG. 7 (d) sequentially show the steps of connecting two sets of moisture separators 3 and 3 into one moisture separator 40 in order.
FIG. 7A shows the existing two moisture separators 3 suspended in a vertical posture in the vertical direction.

  Therefore, as shown in FIG. 7B, the work platform 41 is installed under the two moisture separators 3, and is lowered horizontally on the work platform 41. At this time, the two moisture separators 3 are arranged on the same straight line.

  Next, in FIG. 7 (c), the facing end plates 10 of the two moisture separators 3 are cut and removed, and groove processing is applied to one end of the barrel body 8 that is opened. And all the internal structure sets of each moisture separator 3 are removed. Further, the manhole 16 is closed with a lid. In each moisture separator 3, the steam-in account 13 and the steam-out account 14 can be used even in the horizontal orientation, and therefore groove processing is performed. It should be noted that the hanging bracket 6 and the seats at various places are no longer necessary and are removed.

  Thus, before the body main bodies 8 are welded together, the moisture separation element 9 is newly carried into the inside of the moisture separator 3 whose interior is emptied from the opening from which the end plate 10 is removed. At this time, the moisture separation element 9 carried into each moisture separator 3 is not used for the original vertical moisture separator 3 but is a moisture separation element corresponding to the horizontal moisture separator.

  As shown in FIGS. 8A and 8B, the two moisture separation elements 9a and 9b carried in in this way have the body of the body placed in a new horizontal moisture separator 40 as shown in FIGS. Before being joined to the main body, they are joined together as a horizontal installation for one unit.

  Finally, as shown in FIG. 7 (d), the respective trunk main bodies 8 are welded to be replaced with the main body of one moisture separator 40. In the horizontal moisture separator 40, the manhole 43 and the drain account 44 are newly added because the positions of the manhole and the drain account are different from those in the vertical position.

  As described above, the trunk main bodies 8 of the existing vertical moisture separator 3 can be connected to each other and reused as the horizontal moisture separator 40, and the moisture separation element 9 per unit is added. Capacity can be increased. In addition, since the existing moisture separator 3 can be connected to the trunk main body, and it is easy to upgrade to a larger moisture separator, it is possible to increase the capacity corresponding to the plan for increasing the output of the power generation facility in the future.

The longitudinal cross-sectional view which shows the moisture separator to which the replacement method of the moisture separator internal structure by this invention was applied. It is a cross-sectional view of the moisture separator. The front view which shows the grating | lattice panel of the steam distribution chamber provided in the moisture separator in embodiment of this invention. Sectional drawing which shows the principal part of the moisture separator by other embodiment of the moisture separator internal structure replacement construction method by this invention. Sectional drawing which shows the principal part of the moisture separator by other embodiment of the moisture separator internal structure replacement construction method by this invention. Sectional drawing which shows the principal part of the moisture separator by further another embodiment of the moisture separator internal structure replacement | exchange method by this invention. The side view which shows the process of other embodiment of the moisture separator internal structure replacement | exchange method by this invention. Sectional drawing which shows the inside of the improved moisture separator. The schematic side view which shows arrangement | positioning in the turbine building in which the moisture separator was installed. The top view which shows arrangement | positioning of a moisture separator. The longitudinal cross-sectional view which shows the internal structure of the conventional moisture separator. The cross-sectional view which shows the internal structure of the conventional moisture separator.

Explanation of symbols

3 Moisture Separator 8 Body 9 Moisture Separation Element 10 End Plate 11 Sorase Plate 12 Guide Vane 13 Steam In Account 14 Steam Out Account 15 Drain Out Account 21 Partition Plate 22 Steam Distributing Chamber 23 Outlet Porous Chamber 30 Grid Panel 31 Bolt 32 Nut 40 moisture separator

Claims (1)

A method of removing the deteriorated moisture separation element divided in the longitudinal direction inside the moisture separator body installed in the power plant of the nuclear power plant and replacing it with a new one.
Remove the deteriorated moisture separation element from the inside of the body of the moisture separator, and install a new moisture separation element,
Installing a steam distribution chamber having a grid-like panel parallel to the moisture separation element between the newly replaced moisture separation element and the steam inlet account of the moisture separator body;
An outlet perforated chamber is installed by a perforated panel in which a large number of holes are formed by partitioning between the moisture separation element and the steam outlet account of the moisture separator body, and these steam distribution chamber and outlet perforated chamber are formed The lattice-like panel and the perforated panel are configured to be divided so that they can be carried from a manhole formed in the moisture separator,
A method of replacing a moisture separator internal structure, characterized in that the flow of steam to the moisture separation element is made uniform.

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