JP6461758B2 - Construction method of cylindrical tank - Google Patents

Description

  The present invention relates to a method for constructing a cylindrical tank.

  A double-shell cylindrical tank having an inner tank and an outer tank is used for storing low-temperature liquids such as LNG (liquefied natural gas) and LPG (liquefied petroleum gas). Patent Document 1 discloses a cylindrical tank having a metal inner tank and a concrete outer tank.

  Patent Document 1 discloses a technique for constructing a metal inner tank and a concrete outer tank at the same time in order to shorten the construction period of the cylindrical tank. Specifically, a jack stand is erected at the bottom of the outer tub, and the jack-up device is supported at a predetermined height (see FIG. 4B of Patent Document 1). And when performing the side wall construction of the outer tub, the inner tub roof and the outer tub roof are assembled on the bottom of the outer tub, and then the inner tub roof and the outer tub roof are raised by the jack-up device, By installing the inner tank side plates on the tank roof sequentially from the uppermost one to the lowermost one, the simultaneous construction of the metal inner tank and the concrete outer tank is realized.

Japanese Patent Laid-Open No. 7-62924

  By the way, in the above conventional method, when the inner tank side plate is attached to the lowest level, the inner tank is jacked down and lowered onto the annular part provided at the bottom of the outer tank, and then the anchor strap is attached to the inner tank. The inner tank is completed by welding, and then the cold insulation work between the inner and outer tanks is performed. For this reason, the conventional method has a critical path between the time when the inner tank is fixed to the annular part after the inner tank side plate is attached to the lowest stage, and this construction takes about one month, for example. This is one of the challenges of shortening the construction period.

  Accordingly, the inventors of the present application assemble the second structure, which is the lowermost stage of the inner tank at the bottom of the outer tank, in parallel with the assembly of the first structure except the lowermost stage of the inner tank by the jack-up device. Then, the method of joining the 1st structure and the 2nd structure and assembling the inner tank was devised. According to this method, by separating the lowermost assembly of the inner tank from the assembly of the inner tank by the jack-up device, the inner tank can be fixed forward to the lowermost annular portion. Fixing to the annular part does not become a critical path, and the construction period can be shortened.

  However, in this method, in order to assemble the second structure, which is the lowermost stage of the inner tank, it is necessary to construct a transport system for the inner tank side plate that is different from the first structure assembled above. The inner tank side plate is preferably transported in the circumferential direction of the tank in a horizontal or oblique posture in order to prevent toppling, but in this case, the inner tank side plate needs to be raised after being transported to a predetermined position. Providing an upright stand to raise the inner tank side plate increases the cost because it becomes a huge temporary structure, and the huge temporary structure needs to be dismantled in the tank.

  The present invention has been made in view of the above problems, and the fixing of the inner tank to the annular portion does not become a critical path, the work period can be shortened, and the lowermost stage of the inner tank It is an object of the present invention to provide a method for constructing a cylindrical tank that can complete the transport system for the inner tank side plate with a small-scale temporary installation.

  In order to solve the above-described problems, the present invention is a method of constructing a cylindrical shell having a double shell structure having an inner tank and an outer tank, and an inner tank side plate by a jack-up device inside the outer tank. And the first step of assembling the first structure excluding the lowermost stage of the inner tub, by alternately repeating the rising of the inner tub side plate to the lower side of the raised inner tub side plate, A second step of assembling a second structure, which is the lowest stage of the inner tub, on the annular portion for supporting the inner tub provided at the bottom of the outer tub, the first structure and the A third step of joining the second structure and assembling the inner tub, wherein the second step is a step of installing a rail on the annular portion, and traveling along the rail. The inner tank side plate of the second structure is carried in the circumferential direction of the tank by the conveying device And the transfer device is attached to and detached from the inner tank side plate, a roller device that travels on the rail, an extended support portion that is supported by the roller device and extends in the tank radial direction, and A fall-preventing member that is freely fixed and places the inner tank side plate vertically on the extended support part, and according to the curvature of the inner tank side plate, the extension support part and the fall prevention A method of changing the fixing position with the member is adopted.

  In the present invention, a method is adopted in which the rail is a rail used when the annular material forming the annular portion is transported in the tank circumferential direction.

  Further, in the present invention, the transport device includes a top guide member that is detachably fixed to the inner tank side plate and guides the upper part of the inner tank side plate along the inner peripheral surface of the outer tank. Is adopted.

  In the present invention, the upper guide member includes a length adjustment mechanism that adjusts the length from the upper part of the inner tank side plate to the inner peripheral surface of the outer tank according to the curvature of the inner tank side plate. The method of, is adopted.

  Moreover, in this invention, the said conveying apparatus is provided with the 2nd roller apparatus which drive | works a tank radial direction inner side rather than the said rail, The said extension support part is the said roller apparatus, a said 2nd roller apparatus, Adopted a method that is supported by.

According to the present invention, by separating only the lowermost assembly of the inner tub from the assembly of the inner tub by the jack-up device, the inner tank can be fixed to the lowermost annular portion forward, Fixing the tank to the annular part does not become a critical path, and the construction period can be shortened. Further, according to the present invention, the inner tank side plate is fitted with a fall prevention member, placed on the extended support portion in a vertical posture, and conveyed along the rail installed on the annular portion by the roller device. The inner tank side plate at the lowest stage of the tank can be stably conveyed in a vertical posture. In this way, by transporting the inner tank side plate in a vertical posture, it is not necessary to raise it at a predetermined position, and the transport system for the inner tank side plate at the lowest stage of the inner tank can be completed with a small-scale temporary installation. For this reason, the cost of a conveyance system can be reduced and the process concerning a dismantling operation can be shortened. Since the curvature of the inner tank side plate varies depending on the product, if the inner tank side plate is placed in a vertical posture, it may not get on the rail, but it extends to the transfer device in the tank radial direction. The inner tank side plate in a vertical posture while allowing variation in the curvature of the inner tank side plate by allowing the fixing position of the extended support part and the fall prevention member to be changed according to the curvature of the inner tank side plate. Can be stably conveyed.
Therefore, in the present invention, the fixing of the inner tank to the annular portion does not become a critical path, the work period can be shortened, and the transport system for the inner tank side plate at the lowest stage of the inner tank can be reduced. You can do it temporarily.

It is explanatory drawing which shows the 1st process of the construction method in embodiment of this invention. It is explanatory drawing which shows the 2nd process of the construction method in embodiment of this invention. It is explanatory drawing which shows the 3rd process of the construction method in embodiment of this invention. It is explanatory drawing which shows the 4th process of the construction method in embodiment of this invention. It is a side view which shows the conveying apparatus in embodiment of this invention. It is arrow A figure of FIG. It is a top view which shows the conveying apparatus in embodiment of this invention. It is (a) top view and (b) side view of the extended support part in embodiment of this invention. They are (a) arrow B figure shown in FIG.8 (b), and (b) arrow C figure. It is a top view of the inner tank side board conveyed in the 2nd process of the construction method in the embodiment of the present invention. It is a side view of the inner tank side board lowered | hung to a predetermined position in the 2nd process of the construction method in embodiment of this invention.

  Hereinafter, the construction method of the cylindrical tank of the present invention will be described with reference to the drawings. In the following description, a ground type PC (prestressed concrete) double-shell storage tank for storing LNG is exemplified as the cylindrical tank.

FIG. 1 is an explanatory diagram showing a first step of the construction method according to the embodiment of the present invention.
As shown in FIG. 1, in this method, first, construction of a substantially disk-shaped foundation plate 1 (the bottom of the outer tub) is performed. A base portion 3 for assembling the PC wall 2 (outer tank) is provided on the outer peripheral edge of the base plate 1 in a protruding manner. Moreover, the inner tank anchor strap 4 is installed along the inner side of the foundation part 3. Further, the PC wall 2 is placed on the foundation 3. When placing the PC wall 2, a scaffold 5 is provided and a formwork (not shown) is installed.

  Next, the bottom liner 6 is laid on the foundation plate 1. Moreover, the construction port 8 for taking in the inner tank side plate 9 one by one in the base end part of the PC wall 2 is formed. A plurality of gate-type mounts 10 for assembling the inner tank side plate are installed along the inside of the base end of the PC wall 2. The gate-type gantry 10 is installed so that a cylindrical inner tank formed by combining a plurality of inner tank side plates 9 straddles the annular area X, which is an area to be finally lowered on the base plate 1.

  A rail 200 that conveys the annular material forming the annular portion 13 in the circumferential direction of the tank is suspended from the portal frame 10. The rail 200 is disposed above the annular region X and goes around the tank. The rail 200 is provided with a trolley (not shown) for conveying the annular material. By this trolley, the annular material is conveyed in the circumferential direction of the tank. The conveyed annular material is placed under the portal frame 10 at a predetermined position in the tank circumferential direction.

  Under the gate-type gantry 10, the cold insulation work for the annular portion 13 is performed. As shown in FIG. 5, which will be described later, the cold insulation work of the annular portion 13 is performed by assembling the pearlite concrete blocks 41A and 41B and the structural lightweight concrete block 42 on the bottom cooling resistance reducing material 39, and mounting the annular plate 43 thereon. By doing. The annular portion 13 finally supports the assembled inner tank side plate 9, the annular plate 43 is formed thick, and its cold insulation structure is formed of a hard material such as a concrete block.

  When the cold insulation work of the annular portion 13 is completed, as shown in FIG. 1, the leg portion 10 a disposed inside the tank with respect to the annular portion 13 is replaced on the annular portion 13. By such replacement, there is no interference on the inside of the tank with respect to the annular portion 13, so that the cold insulation work at the center portion on the base plate 1 can be performed. In the cold insulation work in the center, the foam glass 40 is placed on the bottom cooling resistance reducing material 39. Then, a pearlite concrete block (not shown) and an inner tank bottom plate (not shown) are laid on top of each other in this order.

  Further, in the present method, in parallel with the cold insulation work, the inner tank side plate 9 is placed on the gate-type gantry 10 and the adjacent inner tank side plates 9 are welded to each other so as to become a cylindrical shape as a whole. Connect to. Further, the knuckle plate 11 is assembled to the upper end portion of the inner tank side plate 9. In addition, the inner tank roof 14 is assembled on a roof mount (not shown) built in the central portion of the base plate 1 before the cold insulation work in the central portion, and the inner tank side plate 9 is attached to the outer peripheral edge portion via the knuckle plate 11. Assemble.

  Next, in this method, a plurality of jackup devices 18 are installed on the PC wall 2 in the tank circumferential direction. A plurality of knuckle reinforcement members 17 are installed on the knuckle plate 11 in correspondence with the plurality of jackup devices 18. The knuckle reinforcement member 17 projects from the knuckle plate 11 toward the inner / outer tank 15. Further, the knuckle reinforcing member 17 serves as a suspended base. The jack-up device 18 is a center hole jack, and attaches the lower end portion of the jack-up rod 19 to the knuckle reinforcement member 17.

  When the jackup device 18 is installed in this way, a roof mount (not shown) is removed, and the knuckle plate 11 is lifted by the jackup device 18 to raise the inner tank side plate 9. When the jack-up device 18 is raised by one stroke of the jack-up rod 19 (corresponding to the vertical width of the inner tank side plate 9 alone in this embodiment), the jack is raised to the space formed at the lower part of the inner tank side plate 9. The next inner tank side plate 9 is carried in.

  The next inner tank side plate 9 is lifted by the trolley crane 21 and rolls on a roller unit (not shown) installed on the portal frame 10 to a predetermined welding position. On the gate-type gantry 10, the inner tank side plates 9 arranged in an annular shape are welded to each other, and the inner tank side plates 9 arranged in the vertical direction are welded to each other so that the inner tank side plates 9 are integrated into a cylindrical shape. Form. In this way, the raising of the inner tank side plate 9 by the jack-up device 18 and the attachment of the next inner tank side plate 9 to the lower side of the raised inner tank side plate 9 are repeated alternately, and the inner tank side plate 9 is moved to the uppermost position. The first structure 9A excluding the lowermost stage of the inner tank side plate 9 is assembled in order from the upper one.

FIG. 2 is an explanatory diagram showing a second step of the construction method according to the embodiment of the present invention.
In this method, as shown in FIG. 2, the lowermost stage of the inner tank side plate 9 is assembled on the annular portion 13 separately from the first structure 9A. After disassembling the portal frame 10, when the lowermost stage of the inner tank side plate 9 is placed on the annular portion 13, the adjacent inner tank side plates 9 are welded together and joined together in the circumferential direction so as to be cylindrical as a whole. The second structure 9B is assembled. When the second structure 9B is assembled, the inner tank anchor strap 4 installed on the base plate 1 is attached.

  Further, as shown in FIG. 2, the outer tank roof 22 is assembled on the inner tank roof 14. The outer tank roof 22 is connected to the inner tank roof 14 by a connecting material (not shown), and is assembled integrally with the inner tank roof 14. Further, the side liner 2 a is attached to the inner peripheral surface of the PC wall 2. Further, an elevating staircase 23 is provided outside the PC wall 2. Further, the pump barrel 25 is carried inside the PC wall 2.

FIG. 3 is an explanatory diagram showing a third step of the construction method according to the embodiment of the present invention.
Next, in this method, as shown in FIG. 3, the first structure 9A is jacked down, the lower end portion of the first structure 9A is lowered to the upper end portion of the second structure 9B, and the first structure 9A is lowered. The structure 9A and the second structure 9B are welded, and the inner tank 30 is assembled. In this method, the assembly of the lowermost stage of the inner tank 30 is separated from the assembly of the inner tank 30 by the jack-up device 18, and the second structure 9 </ b> B that is the lowermost stage of the inner tank 30 is fixed on the annular portion 13. (See Fig. 2). Therefore, in this method, for example, fixing the inner tank 30 on the annular portion 13 which takes about one month does not become a critical path, and the construction period can be shortened compared to the conventional method.

When the inner tub 30 is completed, the outer tub roof 22 is disconnected from the inner tub roof 14 by a connecting material (not shown) and installed on the upper end of the PC wall 2 assembled to the top. A roof staircase 24 is provided on the outer tank roof 22. A pump barrel 25 is also installed.
Thereafter, the knuckle reinforcement member 17 is cut off and the jackup device 18 is removed. After that, tension work on the PC wall 2 is performed. Then, after the construction port 8 is closed, it is filled with water and a pressure and airtight test is performed.

FIG. 4 is an explanatory diagram showing a fourth step of the construction method according to the embodiment of the present invention.
Finally, as shown in FIG. 4, a cold insulation material 44 is arranged between the inner and outer tanks 15, and the cold insulation material 44 is arranged between the inner tank roof 14 and the outer tank roof 22 to perform the cold insulation work. The cylindrical tank 50 is constructed through painting work and pipe cooling work.

  Thus, according to the above-described embodiment, there is provided a method for constructing a cylindrical shell 50 having a double shell structure having an inner tank and an outer tank. The ascending of the tank side plate 9 and the attachment of the next inner tank side plate 9 to the lower side of the raised inner tank side plate 9 are alternately repeated, and the first structure 9A excluding the lowermost stage of the inner tank 30 is assembled. A first step, a second step of assembling the second structure 9B, which is the lowest stage of the inner tub 30, on the annular portion 13 for supporting the inner tub 30 provided in the base plate 1, and a first step The structure 9A and the second structure 9B are joined to each other, and the third step of assembling the inner tub 30 is employed to fix the inner tub 30 onto the lowest annular portion 13. To the annular portion 13 of the inner tank 30. Fixing does not become the critical path, it is possible to shorten the construction period.

  Hereinafter, the lowermost conveyance system of the inner tank side plate 9 in the second step will be described with reference to FIGS.

  In this method, the assembly of the first structure 9A and the assembly of the second structure 9B are performed in parallel in order to separate the lowermost assembly of the inner tank 30 from the assembly of the inner tank 30 by the jack-up device 18. And do it. Then, apart from the transport system for transporting the inner tank side plate 9 of the first structure 9A in the tank circumferential direction, a system for transporting the inner tank side plate 9 of the second structure 9B in the tank circumferential direction is required. Therefore, in this method, as shown in FIGS. 5 and 6, a transport device 100 that travels along the rail 200 is provided, and the inner tank side plate 9 of the second structure 9 </ b> B is transported in the tank circumferential direction.

FIG. 5 is a side view showing the transport apparatus 100 according to the embodiment of the present invention. 6 is an arrow A view of FIG. FIG. 7 is a plan view showing the transfer apparatus 100 according to the embodiment of the present invention.
As shown in FIG. 5, the transport device 100 includes roller devices 101 </ b> A and 101 </ b> B, an extended support part 110, a tipping prevention member 120, and an upper guide member 130. The transport device 100 travels along the rail 200. As shown in FIG. 1, the rail 200 is hung on the portal frame 10 in the previous step, and is used when conveying the annular material forming the annular portion 13 in the circumferential direction of the tank.

  That is, in the second step, the gate-type gantry 10 is disassembled, but the rail 200 is not disassembled, and is diverted to the lowermost transfer system of the inner tank side plate 9 in the second step. The rail 200 goes around the tank, and can be easily formed as a track around the tank by being installed on the annular portion 13 as it is. Thereby, it is not necessary to prepare the rail 200 separately, and the cost can be extremely reduced.

  As shown in FIGS. 5 and 6, the roller device 101 </ b> A is configured to travel on the rail 200. The roller device 101 </ b> A is disposed immediately below the inner tank side plate 9 and supports the load of the inner tank side plate 9. The roller device 101A is preferably provided with guide rollers (not shown) that guide both sides of the rail 200.

  The extended support part 110 is supported by the roller device 101A. The extended support part 110 extends in the tank radial direction. Specifically, as shown in FIG. 5, the extension support portion 110 extends inward in the tank radial direction from the top of the rail 200 toward the tank center. The inner side in the tank radial direction of the extended support portion 110 is supported by the roller device 101B (second roller device).

FIG. 8 is a (a) plan view and (b) side view of the extended support portion 110 in the embodiment of the present invention. FIGS. 9A and 9B are (a) B view and (b) C view shown in FIG.
As shown in FIG. 8A, the extension support part 110 includes a main body part 111 and an extension part 112 that is detachably fixed to the main body part 111. The main body 111 is supported by the roller device 101A. The extending part 112 is supported by the roller device 101B.

  The main body 111 includes a support plate 113 that supports the lower end of the inner tank side plate 9, and a pair of frames 114 that are fixed to the back surface of the support plate 113. The support plate 113 is formed in a rectangular shape in plan view. The pair of frames 114 are made of a steel material having a predetermined shape (for example, H-shaped steel), and are fixed to the support plate 113 in parallel by welding or the like. Between the pair of frames 114, a roller device 101A is arranged as shown in FIG.

  The roller device 101 </ b> A is disposed on the back side of the support plate 113 and supports the load of the inner tank side plate 9. As the roller device 101A, it is preferable to employ an endless roller mechanism that is excellent in durability and can transport a super-heavy object well. Specifically, a chill tank (registered trademark) can be preferably employed. The support plate 113 is fixed to the top plate 102A of the roller device 101A via a bolt (not shown).

  As shown in FIGS. 8A and 8B, flanges 114 a are provided at the ends of the pair of frames 114. The flange 114a is formed with a hole through which the bolt 115 can be inserted. The bolt 115 fastens and fixes the main body portion 111 and the extending portion 112 by tightening the nut 116. If the fastening of the bolt 115 and the nut 116 is released, the extending part 112 can be separated from the main body part 111. Thus, the extension support part 110 has a configuration in which the configuration (extension length or the like) of the extension part 112 can be changed.

  The extending portion 112 includes a pair of frames 117 fixed to the pair of frames 114 and another pair of frames 118 installed between the pair of frames 117. A flange 117 a is provided at the ends of the pair of frames 117. The flange 117a is formed with a hole through which the bolt 115 can be inserted. The pair of frames 117 are arranged in parallel with the same width as the pair of frames 114.

  The pair of frames 118 is constructed between the pair of frames 117. The pair of frames 118 are arranged in parallel to a direction orthogonal to the pair of frames 117 and are fixed to the pair of frames 117 by welding or the like. As shown in FIG. 9B, a roller device 101B is disposed below one of the pair of frames 118. The roller device 101B supports the load at a position away from the inner tank side plate 9.

  As shown in FIG. 5, the roller device 101 </ b> B travels on the annular plate 43 positioned on the inner side in the tank radial direction from the rail 200. As the roller device 101B, it is preferable to employ a roller mechanism that has a predetermined steering function and is excellent in durability and can transport heavy objects well. Specifically, a chill roller (registered trademark) is preferably employed. be able to. As shown in FIG. 9B, one of the pair of frames 118 is fixed to the top plate 102B of the roller device 101B via a bolt 119.

  As shown in FIG. 5, the fall prevention member 120 is detachably fixed to the inner tank side plate 9. Specifically, a plurality of fixing pieces 9a are welded to the inner tank side plate 9, and the fall prevention member 120 is fixed to the fixing pieces 9a via bolts (not shown). The fall prevention member 120 places the inner tank side plate 9 vertically on the extended support portion 110. The overturn preventing member 120 has a truss structure and prevents the inner tank side plate 9 from overturning.

  Specifically, the fall prevention member 120 includes a triangular frame 121 assembled in a triangle in a side view shown in FIG. 5 and a triangular frame 122 assembled in a triangle in a plan view shown in FIG. The triangular frames 121 and 122 are combined at right angles as shown in FIG. The triangular frames 121 and 122 are made of a steel material having a predetermined shape (for example, H-shaped steel or C-shaped steel), and are fixed by welding or the like. Of the triangular frames 121 and 122, the bottom frame 123 extending in the tank radial direction is made of H-section steel.

  As shown in FIG. 7, the bottom frame 123 can be placed on at least one of the support plate 113 and the pair of frames 118. The bottom frame 123 extends longer than the distance from the support plate 113 to the frame 118. The mounting position of the bottom frame 123 with respect to the extended support portion 110 is configured to be changeable at least in the tank radial direction. The bottom frame 123 is fixed to the support plate 113 and one of the pair of frames 118 via a plurality of vises 124 shown in FIG. According to the fall prevention member 120 having the above-described configuration, the fixing position with the extended support portion 110 can be easily changed in the tank radial direction.

  The upper guide member 130 guides the upper part of the inner tank side plate 9 along the inner peripheral surface of the PC wall 2 as shown in FIG. The upper guide member 130 includes a main body part 131 and a guide part 132. The main body 131 includes a pair of frames 133 and a frame 134 to which the pair of frames 133 are fixed. The pair of frames 133 are fixed to the frame 134 by welding or the like with a distance larger than the thickness of the inner tank side plate 9. A bolt 135 is screwed into one of the pair of frames 133. The main body 131 is detachably fixed to the inner tank side plate 9 by sandwiching the inner tank side plate 9 with bolts 135.

  The guide part 132 includes a frame 136 and a guide roller 137. The guide roller 137 is rotatably attached to the end portion of the frame 136. The frame 136 is fixed to the frame 134 via bolts 138 and nuts 139 shown in FIG. The pair of frames 133, 134, and 136 are made of a steel material having a predetermined shape (for example, C-shaped steel). The frame 134 and the frame 136 are fixed with C-shaped steels back to back.

  As shown in FIG. 5, the upper guide member 130 includes a length adjusting mechanism 140 that adjusts the length from the upper part of the inner tank side plate 9 to the inner peripheral surface of the PC wall 2. The length adjustment mechanism 140 includes a long hole 131 a provided in the main body 131. The long hole 131a extends in the tank radial direction. The long hole 131a makes it possible to change the fixing position in the tank radial direction of the guide part 132 fixed to the main body part 131 by a bolt 138 and a nut 139 (see FIG. 6). The length of the long hole 131 a in the tank radial direction is set to a length that can correspond to the variation in the curvature of the inner tank side plate 9.

Subsequently, the conveyance of the inner tank side plate 9 in the second step using the conveyance system having the above-described configuration will be described with additional reference to FIGS.
FIG. 10 is a plan view of the inner tank side plate 9 conveyed in the second step of the construction method according to the embodiment of the present invention. FIG. 11 is a side view of the inner tank side plate 9 lowered to a predetermined position in the second step of the construction method according to the embodiment of the present invention.

  As described above, in the second step, the second structure 9B, which is the lowest stage of the inner tank 30, is assembled on the annular portion 13 for supporting the inner tank 30 provided at the bottom of the PC wall 2. . The second step includes a step of installing the rail 200 on the annular portion 13. As described above, the rail 200 is suspended from the portal frame 10 in the previous step shown in FIG. 1, and the rail 200 used when the annular material forming the annular portion 13 is conveyed in the tank circumferential direction is used. Thereby, cost can be made extremely small.

  Next, in the second step, the inner tank side plate 9 of the second structure 9B is transported in the tank circumferential direction by the transport device 100 traveling along the rail 200. The conveyance device 100 is detachably fixed to the inner tank side plate 9 and extended to a roller device 101A that runs on the rail 200, an extension support portion 110 that is supported by the roller device 101A and extends in the tank radial direction. And an overturn prevention member 120 for placing the inner tank side plate 9 vertically on the support portion 110. A plurality of transfer devices 100 are installed according to the length of the inner tank side plate 9.

  First, as shown in FIG. 5, the fall prevention member 120 is mounted on the inner tank side plate 9 and placed on the extended support portion 110 in a vertical posture. Next, the fall prevention member 120 and the extended support part 110 are fixed with a vise 124. Further, the upper guide member 130 is fixed to the upper part of the inner tank side plate 9 and is guided along the inner peripheral surface of the PC wall 2. Thereby, the inner tank side plate 9 at the lowermost stage of the inner tank 30 can be stably conveyed in a vertical posture. In this way, by transporting the inner tank side plate 9 in a vertical posture, it is not necessary to raise the inner tank side plate 9 at a predetermined position, and the transport system for the inner tank side plate 9 at the lowest stage of the inner tank 30 can be reduced. You can do it temporarily. For this reason, the cost of a conveyance system can be reduced and the process concerning a dismantling operation can be shortened.

  By the way, the curvature of the inner tank side plate 9 varies depending on the product. For this reason, when the inner tank side plate 9 is in a vertical posture, as shown in FIG. 10, it may not completely get on the rail 200 (see both ends of the inner tank side plate 9 in FIG. 10). For this reason, the extended support part 110 extended in the tank radial direction is provided in the transport apparatus 100, and the fixing position of the extended support part 110 and the fall prevention member 120 can be changed according to the curvature of the inner tank side plate 9. To do. Thereby, the inner tank side plate 9 can be stably conveyed in a vertical posture while allowing variation in the curvature of the inner tank side plate 9. Since the extension support part 110 and the fall prevention member 120 are separate structures, the fixing position can be changed arbitrarily.

  Moreover, in this embodiment, the conveying apparatus 100 is provided with the roller apparatus 101B which drive | works the tank radial direction inner side rather than the rail 200, as shown in FIG. 5, and the extension support part 110 is the roller apparatus 101A and a roller. Supported by the apparatus 101B. According to this method, the fixing position of the extended support part 110 and the fall-preventing member 120 is changed, and the roller device 101B supports the load of the inner tank side plate 9 that is no longer on the rail 200 (roller device 101A). can do. In addition, the roller device 101B is a roller mechanism having a steering function, and can travel well on the annular plate 43 without the rail 200.

  In the present embodiment, the upper guide member 130 adjusts the length from the upper part of the inner tank side plate 9 to the inner peripheral surface of the PC wall 2 according to the curvature of the inner tank side plate 9. Is provided. According to this method, the guide portion 132 can be reliably brought into contact with the inner peripheral surface of the PC wall 2 even if the fixing position of the extended support portion 110 and the fall prevention member 120 is changed. For this reason, it is possible to reliably prevent the inner tank side plate 9 from falling to the outer side in the tank radial direction (PC wall 2 side) while allowing variation in the curvature of the inner tank side plate 9.

  As shown in FIG. 11, when the inner tank side plate 9 is transferred to a predetermined position by the transfer device 100, the inner tank side plate 9 is lifted by a claw jack (not shown), and the anchor 150 is put under the inner tank side plate 9. When the inner tank side plate 9 is replaced with the anchor 150, the roller devices 101A and 101B, the extended support portion 110, and the fall prevention member 120 are removed. Further, the guide portion 132 of the upper guide member 130 is folded inward in the tank radial direction, and the main body 131 is removed by turning the bolt 135. Each removed component member is attached to the inner tank side plate 9 to be transported next.

  Thus, according to the above-described embodiment, a method for constructing a cylindrical tank 50 having a double shell structure including the inner tank 30 and the PC wall 2, and the jackup device 18 inside the PC wall 2. Ascending the inner tank side plate 9 due to the above and attaching the next inner tank side plate 9 to the lower side of the raised inner tank side plate 9 are alternately repeated, and the first structure 9A excluding the lowermost stage of the inner tank 30 is obtained. A first step of assembling, and a second step of assembling the second structure 9B, which is the lowest step of the inner tub 30, on the annular portion 13 for supporting the inner tub 30 provided at the bottom of the PC wall 2. The third step of joining the first structure 9A and the second structure 9B and assembling the inner tub 30 is to install the rail 200 on the annular portion 13. The process and the transport device 100 that travels along the rail 200 make the second Transporting the inner tank side plate 9 of the structure 9B in the tank circumferential direction. The transport device 100 is supported by the roller device 101A traveling on the rail 200 and the roller device 101A in the tank radial direction. An extending support portion 110 that extends, and an overturning prevention member 120 that is detachably fixed to the inner tank side plate 9 and places the inner tank side plate 9 vertically on the extended support portion 110. By adopting a method of changing the fixing position of the extended support portion 110 and the overturning prevention member 120 according to the curvature of the side plate 9, the transport system for the innermost tank side plate 9 at the lowermost stage of the inner tank 30 is reduced. Can be done with a temporary scale.

  As mentioned above, although preferred embodiment of this invention was described referring drawings, this invention is not limited to the said embodiment. Various shapes, combinations, and the like of the constituent members shown in the above-described embodiments are examples, and various modifications can be made based on design requirements and the like without departing from the gist of the present invention.

2 PC wall (outer tank)
DESCRIPTION OF SYMBOLS 9 Inner tank side plate 9A 1st structure 9B 2nd structure 13 Annular part 18 Jackup apparatus 30 Inner tank 50 Cylindrical tank 100 Conveyor apparatus 100A Roller apparatus 100B Roller apparatus (2nd roller apparatus)
110 Extension support part 120 Fall prevention member 130 Upper guide member 140 Length adjustment mechanism 200 Rail

Claims (5)

A construction method of a cylindrical shell of a double shell structure having an inner tank and an outer tank,
On the inner side of the outer tub, the raising of the inner tub side plate by the jack-up device and the attachment of the next inner tub side plate to the lower side of the raised inner tub side plate are alternately repeated, and the lowermost stage of the inner tub is A first step of assembling the first structure to be removed;
A second step of assembling a second structure, which is the lowest stage of the inner tub, on an annular portion for supporting the inner tub provided at the bottom of the outer tub;
Joining the first structure and the second structure, and assembling the inner tub,
The second step includes
A step of installing a rail on the annular portion;
Transporting the inner tank side plate of the second structure in the tank circumferential direction by a transport device that travels along the rail, and
The transport device includes a roller device that travels on the rail, an extension support portion that is supported by the roller device and extends in a tank radial direction, and is detachably fixed to the inner tank side plate and extends. A fall prevention member for vertically placing the inner tank side plate on the support part,
The construction method of the cylindrical tank characterized by changing the fixed position of the said extension support part and the said fall prevention member according to the curvature of the said inner tank side plate.   The said rail is a rail used when conveying the annular material which forms the said annular part to a tank peripheral direction, The construction method of the cylindrical tank of Claim 1 characterized by the above-mentioned.   The said conveyance apparatus is equipped with the upper guide member fixed to the said inner tank side plate so that attachment or detachment is possible, and guides the upper part of the said inner tank side plate along the internal peripheral surface of the said outer tank. The construction method of the cylindrical tank of 2.   The said upper guide member is provided with the length adjustment mechanism which adjusts the length from the upper part of the said inner tank side plate to the inner peripheral surface of the said outer tank according to the curvature of the said inner tank side plate. Item 4. A method for constructing a cylindrical tank according to Item 3. The transport device includes a second roller device that travels on the inner side in the tank radial direction than the rail,
The said extended support part is supported by the said roller apparatus and a said 2nd roller apparatus, The construction method of the cylindrical tank as described in any one of Claims 1-4 characterized by the above-mentioned.

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