KR20210136612A - Insulation wall securing device for liquefied gas storage tank - Google Patents

Abstract

According to the present invention, a liquefied gas storage tank of a dual insulation structure includes a secondary insulation wall comprising a plurality of secondary insulation panels installed on an inner wall of a vessel body, and a primary insulation wall installed in an upper part of the secondary insulation wall and comprising a plurality of primary insulation panels. Moreover, the liquefied gas storage tank includes a device for fixing an insulation wall installed in an upper part of the secondary insulation wall to fix the primary insulation wall. The insulation wall fixing device includes: a base plate placed and fixed in a groove formed in an upper part of the secondary insulation panel; a stud connected to an upper part of the base plate and located between the primary insulation panels adjacent to each other; a spring member connecting the base plate with the stud; a flat washer inserted into the stud and supported by a lower plate of the primary insulation panels; and a locking nut coupled with an upper part of the stud to fix the flat washer while pressing the same downward. Therefore, the present invention is capable of considerably improving the constructability of insulation walls and shortening a construction period.

Description

Insulation wall fixing device for liquefied gas storage tank {INSULATION WALL SECURING DEVICE FOR LIQUEFIED GAS STORAGE TANK}

The present invention relates to a device for fixing an insulating wall of a liquefied gas storage tank, and more particularly, in a liquefied gas storage tank having a double insulating structure including a secondary insulating wall and a primary insulating wall installed thereon, 2 It relates to an insulating wall fixing device for fixing the primary insulating wall to the upper portion of the primary insulating wall.

Liquefied Natural Gas (hereinafter 'LNG') is obtained by cooling natural gas to a cryogenic temperature (approximately -163℃). Very suitable for transport.

In addition, in recent years, as air pollution regulations are strengthened, a technology for using a liquefied gas such as LNG as a propulsion fuel of a ship is being developed.

Cryogenic LNG can be stored in vessels such as LNG Carrier (LNGC), which transports LNG to destinations on land by operating the sea, or LNG Fueled Ship (LFS), which is propelled by using LNG as fuel. A storage tank (commonly referred to as a 'cargo hold') with insulation and sealing structure is provided.

LNG storage tanks are classified into Independent Type and Membrane Type depending on whether the load of cargo directly acts on the insulation, and membrane type storage tanks are usually classified as GTT NO 96 type and MARK Ⅲ type. can be classified.

In general, the membranous storage tank has a double insulation (or double barrier) structure in which the secondary insulating wall, the secondary sealing wall, the primary insulating wall and the primary sealing wall are sequentially stacked from the inner wall of the hull.

For example, in the conventional NO 96 storage tank, the primary and secondary sealing walls are made of Invar (36% nickel steel) membrane, and the primary and secondary insulating walls are perlite powder inside the plywood box. It consists of insulation boxes filled with insulating materials such as

And, in the conventional MARK Ⅲ type storage tank, the primary sealing wall and the secondary sealing wall are each made of a stainless steel (SUS) membrane and a triplex, and the primary and secondary insulating walls are polyurethane foam ( PUF) is composed of insulation panels with wood plywood bonded to the upper or lower surface of the insulator.

As such, in a membranous storage tank equipped with a double-structured insulating wall, the primary insulating wall must be fixed on top of the secondary insulating wall. In the conventional NO 96 storage tank, the insulating box and 1 A fixing device in the form of a double coupler was installed on the inner wall of the hull to simultaneously fix the insulation box constituting the insulation wall of the car. A method of adhering the primary sealing wall with an adhesive and re-adhering the primary insulating wall on top of the secondary sealing wall was applied.

On the other hand, in order to compensate for the disadvantages of fixing the insulation wall in the conventional MARK Ⅲ type storage tank in an adhesive manner, a technique for fixing the primary insulation wall on the upper part of the secondary insulation wall in a mechanical manner is known. .

1 is a view showing a structure in which a primary insulating wall is mechanically fixed to an upper portion of a secondary insulating wall in an LNG storage tank according to the prior art, and FIG. 2 is a plan view looking down from the top of FIG. 1 .

1, in the conventional LNG storage tank, the secondary insulating wall 10, the secondary sealing wall 20, the primary insulating wall 30 and the primary sealing wall (not shown) are sequentially formed on the inner wall of the hull. It has a double insulation structure that is laminated with

The secondary insulating wall 10 includes a secondary insulating material 11 and an upper plate 12 located on the upper part of the secondary insulating material 11 , and the primary insulating wall 30 includes the primary insulating material 31 and It includes a lower plate 32 positioned below the primary insulating material (31).

Here, the primary insulating wall is fixed by the fixing device 40 installed on the upper part of the secondary insulating wall 10 in a state where the secondary sealing wall 20 is interposed between the secondary insulating wall 10 and the secondary insulating wall 10 . is done

The conventional fixing device 40 includes a base socket 41 that is fixedly installed on the upper portion of the secondary insulating wall 10 , a lower end is screwed with the base socket 41 , and an upper end is formed with a secondary sealing wall 20 . A stud 42 extending upward through the stud 42, a flat washer 43 fitted to the stud 42 and supported by the lower plate 32 of the primary heat insulating wall 30, and the upper end of the stud 42 A fixing nut 44 that is fastened to press and fix the flat washer 43 downward, and a spring washer 45 interposed between the flat washer 43 and the fixing nut 44 to absorb the load in the vertical direction. include

The base socket 41 is inserted and fixed into a groove formed by cutting the upper plate 12 of the secondary heat insulating wall 10 . At this time, the base socket 41 must have sufficient thickness in the vertical and horizontal directions to form a space in which the stud 42 is fastened therein.

Therefore, in the conventional LNG storage tank, in order to install the base socket 41, the upper plate 12 of the secondary insulating wall 10 had to be cut with respect to the entire thickness, and in some cases, the upper plate 12 under the upper plate 12 There was also a situation in which a groove had to be formed in the car insulator 11 as well.

In addition, in the prior art, in order to accommodate the horizontally protruding portion at the lower end of the base socket 41, the groove formed in the upper plate 12 had to be formed to be stepped in an approximately 'L' shape, so the groove of a complicated shape Excessive time and labor was consumed for processing.

Looking at the method of fixing the primary insulating wall 30 to the upper part of the secondary insulating wall 10 in the conventional LNG storage tank, the studs 42 are attached to the base socket 41 installed on the upper part of the secondary insulating wall 10 . ), and after sequentially inserting the flat washer 43 and the spring washer 45 into the stud 42 in a state where the primary insulating wall 30 is arranged around the stud 42, the stud 42 ) by fastening the fixing nut 44 to the upper end of the primary heat insulating wall 30 is fixed. That is, the primary insulating wall 30 is fixed in a form in which the flat washer 43 fitted to the stud 42 holds the lower plate 32 of the primary insulating wall 30 .

On the other hand, in the conventional LNG storage tank, since mastic or resin is applied between the secondary insulating wall 10 and the inner wall of the hull, the behavior due to the deformation of the hull is secondary to the insulation through the mastic. directly to the wall 10 .

However, as described above, the conventional LNG storage tank having a structure in which the primary insulating wall 30 is fixed to the fixing device 40 installed on the upper part of the secondary insulating wall 10 is formed by the secondary insulating wall 10 . There was a problem in that the transmitted behavior of the hull was transmitted to the primary thermal insulation wall (30).

Specifically, the behavior of the hull transferred from the conventional LNG storage tank to the secondary insulating wall 10 causes translational and rotational movements of the fixing device 40 (refer to FIG. 2 ), and the primary insulating wall 30 . The load according to the movement is directly transmitted through the fixing device 40 , so the structural stability of the LNG storage tank cannot be easily secured.

At this time, in the conventional fixing device 40, since the stud 42 is directly fastened to the base socket 41 and fixed immovably, the translational/rotational movement induced in the fixing device 40 is performed with the fixing device 40 and 2 There was a problem in that stress was concentrated in the welded portion by acting as a direct load on the welded portion between the primary sealing wall 20 , and a large stress was also applied to the contact surface between the fixing device 40 and the lower plate 32 of the primary insulating wall 30 . , which further impairs the structural stability of the LNG storage tank.

In general, loads occur in several directions inside the LNG storage tank due to the load of cargo or sloshing. You can respond in your own way.

However, as described above, in the conventional LNG storage tank, there is no means to respond to the horizontal load that induces the translational/rotational motion of the fixing device, so that the load due to the behavior of the hull is transmitted to the primary insulation wall side. could not be effectively prevented.

In particular, in recent years, as the cargo hold becomes larger, the thickness of the insulation wall is also gradually increasing. .

Accordingly, in the present invention, in providing a fixing device for fixing an insulating wall in a liquefied gas storage tank for storing cryogenic liquefied gas such as LNG, a means capable of responding to a horizontal load as well as a vertical load generated inside the storage tank is provided. By providing, it is a technical task to minimize the load transferred from the hull to the primary insulating wall, and ultimately to improve the structural stability of the liquefied gas storage tank.

In addition, the present invention achieves the above technical problem, thereby reducing the load acting on the weld between the insulating wall fixing device and the secondary sealing wall, and reducing the load at the contact portion between the insulating wall fixing device and the primary insulating wall want to promote

In addition, the present invention improves the ease of installation by changing the shape and reducing the thickness of the members constituting the base of the insulation wall fixing device, and is structurally stable and lightweight even when the thickness of the primary insulation panel is increased in the future. An object of the present invention is to provide a device for fixing the insulation wall of a storage tank.

According to one aspect of the present invention for achieving the above object, a secondary insulating wall comprising a plurality of secondary insulating panels installed on the inner wall of the hull, and a plurality of primary insulating panels installed on the secondary insulating wall In the liquefied gas storage tank of a double insulated structure including a primary insulating wall made of The device may include: a base plate seated and fixed in a groove formed on an upper portion of the secondary insulation panel; a stud connected to the upper portion of the base plate and positioned between the adjacent primary insulating panels; a spring member connecting the base plate and the stud; a flat washer fitted to the stud and supported by the lower plate of the primary insulation panel; and a locking nut that is fastened to the upper end of the stud and presses the flat washer downward and fixes the locking nut, the insulation wall fixing device of the liquefied gas storage tank may be provided.

The spring member may be provided as a coil spring to easily absorb loads in both vertical and horizontal directions.

A lower end and an upper end of the spring member may be coupled to the base plate and the stud, respectively.

The spring member may be fixed by fastening the base plate and the stud with a bolt/nut.

A connection part provided in a form in which a bolt can be restrained for connection with the base plate and the stud may be formed at the lower end and upper end of the spring member.

The base plate includes a plate-shaped plate portion that is seated and fixed in a groove formed in the upper plate of the secondary heat insulation panel, and a protrusion that protrudes upward from the plate portion, and the protrusion includes the spring member. A first through hole through which a bolt can be inserted for fastening may be formed.

A thread for fastening the locking nut may be formed on an outer circumferential surface of the stud, and a second through hole through which a bolt may be inserted for fastening with the spring member may be formed at a lower end of the stud.

A cylinder-shaped guide may be inserted into the spring member to limit the horizontal movement of the spring member.

The edge of the primary insulating panel is formed with a lower plate partially exposed for fixing with the insulating wall fixing device, and a wedge for height adjustment between the exposed lower plate of the primary insulating panel and the flat washer Blocks may be placed.

In addition, according to another aspect of the present invention for achieving the above object, the liquefied gas of a double insulation structure including a secondary insulation wall installed on the inner wall of the hull and a primary insulation wall installed on the upper portion of the secondary insulation wall In the storage tank, the stud is connected to the upper part of the base plate installed on the upper part of the secondary insulating wall, and a flat washer is inserted into the stud and supported on the lower plate of the primary insulating wall, the upper end of the stud By fastening a locking nut to the upper part of the secondary insulating wall, the primary insulating wall is fixed on the upper part of the secondary insulating wall, and the base plate and the stud are connected via a spring member having elasticity in vertical and horizontal directions as a medium. The load in the vertical and horizontal directions generated inside the liquefied gas storage tank is absorbed by the spring member, characterized in that it prevents the movement by the hull from being transmitted to the primary insulating wall, liquefied gas storage A device for securing the insulating wall of the tank may be provided.

The spring member may be a coil spring made by winding a wire rod having a circular or square cross-section in a coil state.

The spring member may be a tension coil spring.

The device for fixing the insulation wall of a liquefied gas storage tank according to the present invention enables flexible response to horizontal loads as well as vertical loads generated inside the storage tank by means of a spring member connecting between the base plate and the stud, so that the hull It is possible to minimize the load transferred from the to the primary insulation wall, and accordingly, there is an effect that the structural stability of the liquefied gas storage tank is remarkably improved.

Further, according to the present invention, as the translational/rotational motion induced in the insulating wall fixing device is reduced, the load acting on the welding portion of the insulating wall fixing device and the secondary sealing wall and the contact portion between the insulating wall fixing device and the primary insulating wall. is reduced and it is possible to effectively prevent the concentration of stress in the corresponding region, and thus has the effect of promoting higher structural stability of the liquefied gas storage tank.

In addition, according to the present invention, it is possible to form a thin thickness of the member (base plate) constituting the base of the insulating wall fixing device, there is no need to form a difficult-to-process step in the upper plate of the secondary insulating wall. Since it is sufficient to form a relatively simple groove in the upper plate of the secondary insulating wall in order to provide a space in which the base plate is seated, there is an effect that the workability of the primary insulating wall is remarkably improved compared to the prior art.

In addition, in the present invention, since the secondary sealing wall is welded on the base plate rather than the studs of the insulating wall fixing device to form a seal, a step is formed on the lower plate of the primary insulating wall to avoid interference when the stud is made of a collar stud. The processing process can be deleted, and accordingly, the installation process of the insulating wall fixing device is simplified, thereby reducing the working time.

1 is a view showing a structure in which a primary insulating wall is mechanically fixed to an upper portion of a secondary insulating wall in an LNG storage tank according to the prior art.
FIG. 2 is a plan view of FIG. 1 as viewed from above.
3 is a view showing a structure in which the primary insulating wall is fixed to the upper portion of the secondary insulating wall in the liquefied gas storage tank according to the present invention.
4 is a view showing an insulating wall fixing device according to the present invention.
5 is a view showing a coupling structure between the base plate and the spring member in the insulation wall fixing device according to the present invention.
6 is a view showing that the insulation wall fixing device according to the present invention is bent in response to a horizontal load.

In order to fully understand the present invention, the operational advantages of the present invention, and the objects achieved by the practice of the present invention, reference should be made to the accompanying drawings illustrating preferred embodiments of the present invention and the contents described in the accompanying drawings.

In the present invention, the use of the terms 'primary' and 'secondary' refers to whether the primary sealing or insulating function or the secondary sealing or insulating function is performed based on the liquefied gas stored in the storage tank. It is used as a classification criterion.

Also, customarily the terms 'upper' or 'above' applied to elements of a storage tank refer to the direction toward the inside of the storage tank, irrespective of the direction to gravity, likewise the terms 'bottom' or 'down' Regardless of the direction, it indicates the direction toward the outside of the storage tank.

In the present invention, 'liquefied gas' is liquefied at a low temperature such as LNG, LPG (Liquefied Petroleum Gas), LEG (Liquefied Ethane Gas), liquefied ethylene gas (Liquefied Ethylene Gas), liquefied propylene gas (Liquefied Propylene Gas), etc. It may contain any kind of liquefied gas that can be stored and transported.

Hereinafter, the present invention will be described in detail by describing preferred embodiments of the present invention with reference to the accompanying drawings. Like reference numerals in each figure indicate like elements.

3 is a view showing the structure in which the primary insulating wall is fixed to the upper part of the secondary insulating wall in the liquefied gas storage tank according to the present invention, FIG. 4 is a view showing the insulating wall fixing device according to the present invention, FIG. is a view showing the coupling structure between the base plate and the spring member in the insulation wall fixing device according to the present invention. And Figure 6 is a view showing that the insulation wall fixing device according to the present invention is bent in response to a horizontal load.

Referring to FIG. 3, the liquefied gas storage tank according to the present invention includes a secondary insulating wall configured by sequentially arranging a plurality of secondary insulating panels 10 on the inner wall of a hull, and 2 installed on the secondary insulating wall. A primary insulating wall comprising a primary sealing wall 20, a plurality of primary insulating panels 30 sequentially arranged on the upper portion of the secondary sealing wall 20, and a primary installed on the primary insulating wall It may have a double insulation (or double barrier) structure including a sealing wall (not shown).

The secondary insulating panel 10 may be provided in the form of a sandwich panel including a secondary insulating material 11 made of polyurethane foam (PUF) and an upper plate 12 attached to an upper portion of the secondary insulating material 11 . In addition, a plurality of secondary thermal insulation panels 10 provided as a unit unit may be arranged in succession on the inner wall of the hull to constitute a secondary thermal insulation wall.

Similarly, the primary insulating panel 30 is a sandwich panel type including a primary insulating material 31 made of polyurethane foam (PUF) and a lower plate 32 attached to the lower portion of the primary insulating material 31 . may be provided, and a plurality of primary insulating panels 30 provided as a unit unit may be arranged in succession on the upper portion of the secondary sealing wall 20 to constitute a primary insulating wall.

In the present invention, the primary sealing wall (not shown) and the secondary sealing wall 20 are provided with a membrane made of a metal material and can function to primarily/secondarily seal the liquefied gas stored inside the storage tank. .

In addition, the liquefied gas storage tank according to the present invention may include an insulating wall fixing device 100 for fixing the primary insulating wall to the upper portion of the secondary insulating wall.

The installation of the primary insulating wall is performed in a state where the secondary sealing wall 20 is interposed between the secondary insulating wall and the insulating wall fixing device 100 installed on the upper part of the secondary insulating panel 10 . This may be accomplished by fixing the car insulation panel 30 .

3 to 5, the insulation wall fixing device 100 of the present invention, the base plate 110 is seated and fixed in the groove formed in the upper portion of the secondary insulation panel (10); The stud 120 is connected to the upper portion of the base plate 110 and located between the adjacent primary insulating panels 30; a spring member 130 connecting between the base plate 110 and the stud 120 ; A flat washer 140 fitted to the stud 120 and supported by the lower plate 32 of the primary heat insulation panel 30; and a locking nut 150 that is fastened to the upper end of the stud 120 to press and fix the flat washer 140 downward.

Here, the edge of the primary insulating panel 30 may be formed in a state in which the lower plate 32 is partially exposed for fixing with the insulating wall fixing device 100 , and the exposed edge of the primary insulating panel 30 is A wedge block 33 may be disposed between the lower plate 32 and the flat washer 140 for height adjustment. The wedge block 33 may be provided as a block of plywood material.

The base plate 110 includes a plate-shaped plate portion 111 that is seated and fixed in a groove formed in the upper plate 12 of the secondary heat insulation panel 10; and a pipe-shaped (or cylindrical) protrusion 112 protruding upward from the plate portion 111 .

In the present invention, the base plate 110 is not directly fastened with the stud 120, but is connected via the spring member 130, so a space for fastening with the stud 120 is provided inside the base plate 110. There is no need to do so, and thus the thickness in the vertical and horizontal directions can be significantly reduced compared to the conventional fixing device 40 (refer to FIG. 1).

That is, it is sufficient if the plate portion 111 in the base plate 110 is formed only with a thickness sufficient to secure the fastening force with the secondary insulation panel 10 and to withstand the load applied to the insulation wall fixing device 100 . .

According to the structure of the present invention, it is possible to significantly reduce the thickness of the plate portion 111 fixed to the upper portion of the secondary heat insulation panel 10 in the base plate 110 as described above, as in the prior art, the base socket 41 ( FIG. 1 ). Note) to accommodate the lower protrusion of the upper plate 12, there is no need to form a stepped groove, and only a relatively simple groove corresponding to the shape of the plate portion 111 is formed, the ease of installation is remarkable compared to the prior art. It has a significantly improved effect.

The upper plate 12 of the secondary insulation panel 10 may be partially cut with respect to the entire thickness in order to provide a space in which the plate part 111 is seated, and the plate part 111 is a groove of the upper plate 12 . It may be fixed by a fastening member such as a rivet or a screw in a state of being seated on the surface, or may be fixed by an adhesive method using an adhesive.

In addition, since the protrusion 112 in the base plate 110 does not need to form a space in which the stud 120 is to be inserted, the thickness in the horizontal direction can be significantly reduced compared to the prior art, as shown in FIG. As shown, it is possible to position the protrusion 112 at the level of the primary insulating wall rather than the level of the secondary insulating wall. That is, in the present invention, the upper surface of the plate portion 111 of the base plate 110 forms the same plane as the upper surface of the secondary insulation panel 10, and the protrusion 112 of the base plate 110 is the secondary insulation panel ( 10) may be formed to protrude upward.

As described above, according to the structure of the present invention, it is possible to greatly reduce the thickness of the protrusion 112 in the base plate 110 and position it at the level of the primary insulating wall, the insulating wall fixing device 100 at the level of the secondary insulating wall. ), as the structure of the part where it is installed is greatly simplified, there is an effect that the workability of the primary insulation wall is remarkably improved.

On the other hand, the protrusion 112 may be formed with a through hole (h1) into which the bolt (b) can be inserted in the horizontal direction for bolt/nut fastening with the spring member 130 .

The stud 120 may be a member of a pipe shape (or a cylindrical shape), and is not directly coupled to the base plate 110 as in the prior art, but is connected to the base plate 110 via the spring member 130 . .

A thread for fastening the locking nut 150 may be formed on the outer circumferential surface of the stud 120 , and the bolt b may be inserted into the lower end in the horizontal direction for bolt/nut fastening with the spring member 130 . A hole h2 may be formed.

The spring member 130 may be a coiled spring made by twisting a metal material having elasticity in a spiral shape of at least two or more layers. That is, the spring member 130 may be a coil spring made by winding a circular or square-shaped wire in a coil state, preferably a tension coil spring.

Although the drawing shows that the spring member 130 is provided as a cylindrical coil spring having a circular cross section, the spring member 130 may be provided to have a rectangular or more polygonal cross section.

Stainless steel (SUS) may be used as the material of the spring member 130 , and the outer diameter, number of turns, and the diameter of the coil, etc. It can be designed considering the calculation) and the width of the installation space.

The spring member 130 may have a lower end and an upper end fixed to the base plate 110 and the stud 120 by bolt/nut fastening, respectively.

Connection parts 131 for connection with the base plate 110 and the stud 120 may be formed at upper and lower ends of the spring member 130 , respectively. The connection part 131 may be provided in a form in which the bolt b is supported by being caught or inserted therethrough to be constrained.

The fixing between the spring member 130 and the base plate 110 is, as shown in FIG. 5, in a state in which the protrusion 112 of the base plate 110 is partially inserted into the spring member 130, a bolt ( After inserting b) to pass through the through hole h1 formed in the connection part 131 and the protrusion 112 of the spring member 130 at the same time, it can be made by fastening the nut n to the end of the bolt b. have. At this time, a washer w may be interposed between the bolt b and the protrusion 112 and between the bolt b and the connection part 131 , respectively.

The fixing between the spring member 130 and the stud 120 may be performed in the same manner, and a detailed description thereof will be omitted.

In the present invention, since the spring member 130 connecting between the base plate 110 and the stud 120 has elasticity not only in the vertical direction but also in the horizontal direction, the vertical load generated inside the storage tank as well as the horizontal load A flexible response is also possible. For example, referring to FIG. 6 , it can be seen that the spring member 130 is flexibly bent in the horizontal direction to easily absorb the load acting in the horizontal direction.

However, in order to prevent excessive deformation according to the height of the spring member 130 , a cylinder-shaped guide may be inserted into the inside of the spring member 130 to limit the horizontal movement of the spring member 130 . have. In this case, the guide member may also use a metal material such as stainless steel (SUS).

The flat washer 140 may have a through-portion formed in the center so that the stud 120 and the locking nut 150 can be inserted therethrough, and in addition to a normal flat washer, an annular setting plate having an inner diameter (setting) plate) may be provided.

The locking nut 150 is fastened to the upper end of the stud 120 and serves to fix the flat washer 140 . That is, by fastening the locking nut 150 , the flat washer 140 holds the lower plate 31 of the primary insulation panel 30 , whereby the primary insulation panel 30 may be fixed.

On the other hand, in the drawings, it is shown that the locking nut 150 has a 'T'-shaped cross section and is provided in the form of a rivet nut or a flange nut in which a thread is formed inside the tube, but in the present invention The locking nut 150 may have various shapes, including a general hexagonal nut, and of course, the locking nut 150 may be located only at the upper portion without passing through the flat washer 140 .

In the insulation wall fixing device 100 according to the present invention having the structure as described above, the base plate 110 and the stud 120 are not directly fastened, but are connected via the spring member 130, the spring member 130 ) in the form of a coil spring that can easily absorb loads in both the vertical and horizontal directions, it is possible to minimize the load transferred from the hull to the primary insulating wall through the secondary insulating wall. There is an effect that the structural stability of the gas storage tank is remarkably improved.

In addition, as the translation/rotational motion induced in the insulating wall fixing device 100 is reduced by the function of the spring member 130 described above, the welding portion of the insulating wall fixing device 100 and the secondary sealing wall 10 and Since the load acting on the contact part between the insulating wall fixing device 100 and the primary insulating wall is reduced, it is possible to effectively prevent the concentration of stress in the corresponding part.

In addition, in the insulation wall fixing device 100 according to the present invention, since both the vertical and horizontal loads generated in the storage tank can be absorbed by the spring member 130, a conventional spring washer (45, FIG. 1) Note) can be omitted.

Hereinafter, a method of fixing the primary insulating wall on the upper portion of the secondary insulating wall in the liquefied gas storage tank according to the present invention will be described in detail.

First, the installation of the insulating wall fixing device 100 is made on the upper portion of the secondary insulating panel 10 constituting the secondary insulating wall. At this time, the insulation wall fixing device 100 may include a state in which the coupling of the base plate 110, the spring member 130, and the stud 120 is completed, and the flat washer 140 and the locking nut 150 are excluded. .

Here, the operation of installing the insulating wall fixing device 100 on the secondary insulating panel 10 is made in advance in the process of manufacturing the secondary insulating panel 10 in an external factory, or the secondary insulating panel on the inner wall of the hull. It may be made after the installation work of (10) is completed.

That is, as described above, in the present invention, since a groove of a complicated shape is not machined in the upper plate 12 of the secondary insulating panel 10 for installation of the base plate 110, the secondary insulating panel 10 ), it is possible not only to reduce the thickness of the upper plate 12, but also to process a relatively simple groove in the upper plate 12 to simply install the base plate 110. That is, according to the present invention, the installation work of the insulating wall fixing device 100 can be easily performed inside the storage tank, and accordingly, the advantage of being able to flexibly determine the installation process sequence of the insulating wall fixing device 100 can be derived. have.

After the operation of installing the secondary insulation panel 10 on the inner wall of the hull and the operation of installing the insulation wall fixing device 100 on the upper portion of the secondary insulation panel 10 are completed, the secondary insulation on the upper portion of the secondary insulation wall is completed. The operation of installing the sealing wall 20 is made.

At this time, the secondary sealing wall 20 is formed with a hole through which the protrusion 112 of the base plate 110 passes, and the inner circumferential surface of the hole formed in the secondary sealing wall 20 is the plate portion ( 111) may be welded to the upper surface to form a seal.

When the installation of the secondary sealing wall 20 is completed, the primary insulating panel 30 is disposed around the insulating wall fixing device 110: 120, 130 protruding to the upper part of the secondary sealing wall 20, By inserting the flat washer 140 into the stud 120 and then fastening the locking nut 150 to fix the lower plate 32 of the primary insulating panel 30, installation and fixing of the primary insulating wall can be made. have.

At this time, a wedge block 33 for height adjustment is installed on the exposed lower plate 32 of the primary insulation panel 30 , and the flat washer 140 may be supported on the wedge block 33 . has been described above.

The present invention is not limited to the described embodiments, and it is apparent to those skilled in the art that various modifications and variations can be made without departing from the spirit and scope of the present invention. Accordingly, it should be said that such modifications or variations are included in the claims of the present invention.

10: secondary insulation panel
11: secondary insulation material
12: upper plate
20: secondary sealing wall
30: primary insulation panel
31: primary insulation material
32: lower plate
33: wedge block
100: insulation wall fixing device
110: base plate
111: plate part
112: protrusion
120: stud
130: spring member
131: connection part
140: flat washer
150: locking nut
b: bolt
h1, h2 : through hole
n: nut
w : washer

Claims (12)

Liquefied gas of a double insulation structure including a secondary insulating wall made of a plurality of secondary insulating panels installed on the inner wall of the hull, and a primary insulating wall installed on the second insulating wall and composed of a plurality of primary insulating panels In the storage tank,
and a thermal insulation wall fixing device installed on the second thermal insulation wall to fix the primary thermal insulation wall,
The insulation wall fixing device,
a base plate seated and fixed in a groove formed on an upper portion of the secondary insulation panel;
a stud connected to the upper portion of the base plate and positioned between the adjacent primary insulating panels;
a spring member connecting the base plate and the stud;
a flat washer fitted to the stud and supported by the lower plate of the primary insulation panel; and
It is fastened to the upper end of the stud comprising a locking nut for pressing and fixing the flat washer downward,
Insulation wall fixing device of liquefied gas storage tank. The method according to claim 1,
The spring member is characterized in that it is provided as a coil spring so as to easily absorb both the vertical and horizontal loads,
Insulation wall fixing device of liquefied gas storage tank. 3. The method according to claim 2,
The spring member is characterized in that the lower end and the upper end are coupled to the base plate and the stud, respectively,
Insulation wall fixing device of liquefied gas storage tank. 4. The method according to claim 3,
The spring member is characterized in that it is fixed by the bolt / nut fastening with the base plate and the stud,
Insulation wall fixing device of liquefied gas storage tank. 5. The method according to claim 4,
In the lower and upper ends of the spring member, a connection portion provided in a form in which a bolt can be constrained for connection with the base plate and the stud is formed,
Insulation wall fixing device of liquefied gas storage tank. 6. The method of claim 5,
The base plate includes a plate-shaped plate portion seated and fixed in a groove formed in the upper plate of the secondary insulation panel, and a protrusion protruding upward from the plate portion,
A first through hole through which a bolt can be inserted for fastening with the spring member is formed in the protrusion,
Insulation wall fixing device of liquefied gas storage tank. 7. The method of claim 6,
A thread for fastening the locking nut is formed on the outer circumferential surface of the stud, and a second through hole through which a bolt can be inserted for fastening with the spring member is formed at the lower end of the stud,
Insulation wall fixing device of liquefied gas storage tank. 5. The method according to claim 4,
A cylindrical guide is inserted into the inside of the spring member so as to limit the horizontal movement of the spring member,
Insulation wall fixing device of liquefied gas storage tank. The method according to claim 1,
The edge of the primary insulation panel is formed with a lower plate partially exposed for fixing with the insulation wall fixing device, and a wedge for height adjustment between the exposed lower plate of the primary insulation panel and the flat washer characterized in that the block is arranged,
Insulation wall fixing device of liquefied gas storage tank. In the liquefied gas storage tank of the double insulated structure comprising a secondary insulating wall installed on the inner wall of the hull and a primary insulating wall installed on the upper part of the secondary insulating wall,
The stud is connected to the upper part of the base plate installed on the upper part of the secondary insulating wall, and a locking nut is fastened to the upper end of the stud while being supported on the lower plate of the primary insulating wall by inserting a flat washer into the stud. By doing so, the primary insulating wall is fixed on the upper part of the secondary insulating wall,
The base plate and the stud are connected via a spring member having elasticity in vertical and horizontal directions, so that the load in the vertical and horizontal directions generated inside the liquefied gas storage tank is absorbed by the spring member. , characterized in that it prevents the movement by the hull from being transmitted to the primary insulating wall,
Insulation wall fixing device of liquefied gas storage tank. 11. The method of claim 10,
The spring member is a coil spring made by winding a wire rod having a circular or square cross section in a coil state,
Insulation wall fixing device of liquefied gas storage tank. 12. The method of claim 11,
The spring member is characterized in that the tension coil spring,
Insulation wall fixing device of liquefied gas storage tank.

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