KR101652220B1 - Cargo for liquefied gas - Google Patents

Abstract

A liquefied gas holding window comprising an insulating panel structure is disclosed. The liquefied gas holding window according to an embodiment of the present invention includes an insulating panel assembly surrounding a main wall surrounding a space for accommodating liquefied gas and insulating the liquefied gas from the outside, and the insulating panel assembly includes a lower insulating panel, An auxiliary barrier provided on the lower insulating panel to seal the lower insulating panel and including a flat portion and a convex wrinkle portion in a direction in which the main wall is provided, and an upper insulating panel laminated on the auxiliary wall, Is provided with a receiving groove capable of receiving the wrinkles of the auxiliary barrier.

Description

{CARGO FOR LIQUEFIED GAS}

The present invention relates to a liquefied gas hold, and more particularly, to a liquefied gas hold including an insulating panel structure.

Liquefied gas is a liquid made by cooling or compressing gas, and consumption of liquefied gas such as Liquefied Natural Gas (LPG) or LPG (Liquefied Petroleum Gas) is rapidly increasing worldwide.

Liquefied natural gas (LNG), which is an example of liquefied gas, refers to a colorless transparent cryogenic liquid having a volume of methane-based natural gas cooled to -162 ° C and reducing its volume by one-sixth, In order to utilize natural gas as energy, efficient transportation methods have been examined that can be mass-shipped from the production base to the destination of the demand site. As part of this effort, a liquefied natural gas transport vessel capable of transporting large volumes of liquefied natural gas to sea was developed.

The liquefied natural gas transportation vessel must have a cargo which can store and store the liquefied natural gas liquefied at a cryogenic temperature.

That is, since the liquefied natural gas has a higher vapor pressure than the atmospheric pressure and has a boiling temperature of about -162 ° C, in order to safely store and store such liquefied natural gas, For example, it should be made of aluminum steel, stainless steel, 35% nickel steel, etc. It should be designed with a unique insulation panel structure which is resistant to thermal stress and heat shrinkage and prevents heat penetration. Such a cargo hold of a liquefied natural gas transportation vessel can be divided into a self-supporting type and a membrane type depending on its structure.

Korean Patent Laid-Open Publication No. 10-2012-0013233 (Feb. 14, 2012) discloses a liquefied natural gas storage tank and a manufacturing method thereof.

Korean Published Patent Application No. 10-2012-0013233 (2012.02.14.)

An embodiment of the present invention is to provide a liquefied gas holding window in which the corrugation of the auxiliary barrier protrudes toward the upper insulating panel.

Another object of the present invention is to provide a liquefied gas cargo hold capable of supporting an impact due to a sloshing load while forming a receiving groove capable of receiving the corrugation of the auxiliary barrier in the upper insulating panel.

According to an aspect of the present invention, there is provided a liquefied gas holding window including a heat insulating panel assembly surrounding a main wall surrounding an accommodating space for accommodating a liquefied gas and insulating the liquefied gas from the outside, Lower insulation panel; An auxiliary barrier provided on the lower heat insulating panel to seal the lower heat insulating panel and including a flat portion and a convex wrinkle portion in a direction in which the kitchen wall is installed; And an upper insulating panel laminated on the auxiliary barrier. The liquefied gas holding window may be provided on the bottom of the upper insulating panel to have a receiving groove for receiving the wrinkles of the auxiliary barrier.

A flat portion of the auxiliary barrier may support the upper insulating panel and a receiving groove of the upper insulating panel may be spaced apart from the corrugation of the auxiliary barrier.

The inner side surface shape of the receiving groove of the upper insulating panel corresponds to the outer side surface shape of the corrugated portion of the auxiliary barrier.

The inner side surface of the receiving groove of the upper insulating panel may be provided to be in contact with the corrugation of the auxiliary barrier.

And a panel fixing unit installed on the lower insulation panel to fix the upper insulation panel. The upper insulation panel includes an upper first insulation panel and a lower panel provided below the upper first insulation panel, And an upper second heat insulating panel provided at a lower portion of the upper reinforcing panel and having a bottom portion which is seated on a flat surface portion of the auxiliary wall and is provided with a receiving groove capable of receiving the corrugation of the auxiliary wall, A gas hold can be provided.

Wherein the pleats comprise a first pleat portion arranged in a first direction and a second pleat portion arranged in a second direction different from the first direction and an intersection where the first pleat portion and the second pleat portion intersect, The groove includes a first receiving groove for receiving the first wrinkle portion, a second receiving groove for receiving the second wrinkle portion, and a second receiving groove for receiving the intersecting portion, A liquefied gas storage chamber may be provided.

The upper first insulation panel, the upper reinforcement panel, and the upper second insulation panel may be provided with a liquefied gas cargo hold having the same width direction shape.

Wherein the upper reinforcing panel and the upper second insulating panel include through holes through which protruding members of the panel fixing unit pass, the upper first upper heat insulating panel including through holes for receiving the projecting members, The liquefied gas holding window in which the diameter of the through-hole of the single-adiabatic panel is larger than the diameter of the through-hole of the reinforcing panel may be provided.

A liquefied gas holding window having the same through-hole as the reinforcing panel and the through-hole of the upper second insulating panel may be provided.

The upper first and second upper and lower heat insulating panels may be provided with a liquefied gas holding window made of the same material.

And the upper second heat insulating panel may be provided with a liquefied gas holding window including a penetration portion connected to the receiving groove.

The penetrating portion may be provided with a liquefied gas holding window vertically positioned to correspond to a floor of the auxiliary barrier rib portion.

The penetrating portion may be provided with a liquefied gas holding window for cutting the upper second heat insulating panel.

And a spacer provided between the flat portion of the auxiliary barrier and the upper reinforcing panel.

The panel fixing unit may include a protruding member penetrating the upper second insulation panel and the upper reinforcing panel, and the spacer may be provided with the liquefied gas holding window provided to receive the protruding member therein.

The panel fixing unit may further comprise a coupling member coupled to the lower heat insulating panel and to which the projection member is fixed, and the spacer may be provided with a liquefied gas holding window that is seated on the coupling member.

A liquefied gas holding window may be provided on the bottom surface of the upper insulating panel to provide a friction reducing member capable of reducing friction with the auxiliary barrier.

The liquefied gas holding window may be provided on the bottom surface of the upper insulating panel, wherein the liquefied gas holding window is provided with an impact absorbing member capable of absorbing an impact transmitted to the auxiliary wall.

The liquefied gas holding window according to the embodiment of the present invention may protrude the corrugated portion of the auxiliary barrier toward the upper insulating panel to facilitate the installation and maintenance of the auxiliary barrier.

Also, the reinforcing panel is inserted between the upper first heat insulating panel and the upper second heat insulating panel formed with the receiving groove, while the corrugated portion of the auxiliary wall protrudes toward the upper heat insulating panel, so that the rigidity of the upper heat insulating panel can be maintained.

Further, by including the shock absorbing member, the heat insulating panel can be protected from the sloshing load.

1 is a partial perspective view of a liquefied gas holding window according to a first embodiment of the present invention.
2 is a cross-sectional view showing a structure of a liquefied gas holding window according to a first embodiment of the present invention.
3 is an exploded perspective view showing an assembled state of the auxiliary barrier.
4 is an enlarged view of Fig.
Fig. 5 is an exploded perspective view showing a state in which the upper insulating panel is engaged.
Fig. 6 is an enlarged view of Fig. 2 showing an upper insulating panel structure according to the first embodiment of the present invention. Fig.
Fig. 7 is a perspective view showing a state of engagement of the kitchen wall. Fig.
8 is a cross-sectional view showing an upper insulating panel structure according to a second embodiment of the present invention.
9 is a cross-sectional view showing an upper insulating panel structure according to a third embodiment of the present invention.
10 is a sectional view showing an upper insulating panel structure according to a fourth embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The embodiments described below are provided by way of example so that those skilled in the art will be able to fully understand the spirit of the present invention. The present invention is not limited to the embodiments described below and may be embodied in other forms. In order to clearly explain the present invention, parts not related to the description are omitted from the drawings, and the width, length, thickness, etc. of the components may be exaggerated for convenience. Like reference numerals designate like elements throughout the specification.

The liquefied gas holding window according to an embodiment of the present invention can be used to store and / or transport cryogenic liquefied gas. The liquefied gas is made of liquid by cooling or compressing the gas, and includes liquefied natural gas (LNG), liquefied petroleum gas (LPG), dimethyl ether (DME) and the like .

Liquefied gas cargo holds are used to transport liquid gas such as LNG carrier, LNG RV (Regasification Vessel) carrier, LPG carrier or ethylene carrier, FSRU (Floating Storage Regulation Unit), FPSO (Floating Production Storage Offloading) Or Barge Mounted Power Plant (BMPP), or to marine floating plants with vaporization facilities. In addition, the liquefied gas cargo holds include not only the facilities installed on the sea, but also those used for facilities to store or produce liquefied gas installed on land.

Hereinafter, a membrane-type cargo hold of a liquefied gas holding cargo will be described as an example. FIG. 1 is a perspective view showing a partially assembled state of a liquefied gas holding window according to a first embodiment of the present invention, and FIG. 2 is a sectional view showing the structure of a liquefied gas holding window according to a first embodiment of the present invention .

1 and 2, the liquefied gas holding window surrounds a space capable of accommodating the liquefied gas and includes a main wall 50 in direct contact with the liquefied gas, and a lid 40 surrounding the main wall 50, And an outer wall 10 which surrounds and firmly supports the heat insulating panel assembly.

The kitchen wall 50 is for sealing the storage space in which the storage fluid is received, and requires airtightness (or watertightness). Liquefied gas is usually stored in a liquid state because it can be kept at a cryogenic temperature below the boiling point. However, depending on the change of temperature or pressure, vaporization of some liquefied gas may occur, and the pressure inside the cargo hold increases greatly. When the kitchen wall 50 penetrates due to such an increase in pressure or the like, the liquid or gaseous liquefied gas can be introduced into the insulating panel assembly. As the temperature of the introduced liquefied gas increases, the volume rapidly expands and damages the heat insulating panel assembly. The damage to the cargo holds a significant amount of time and money in repairs, so the airtightness of the barrier is considered very important.

Metal material such as an invar alloy (INVAR), stainless steel (SUS), or an aluminum alloy can be used to maintain the physical and chemical conditions of the kitchen wall 50 even at a low temperature. The kitchen wall 50 may be formed by connecting a plurality of kitchen wall 50 sheets and may be welded to each other to maintain airtightness.

As a method of welding the kitchen wall 50, various welding methods used in the related art can be used and include lap welding or butt welding. An automatic welding apparatus using laser welding or plasma welding may also be used to improve uniformity of work quality while improving welding quality. Above-mentioned lap welding, butt welding, laser welding, plasma welding, etc. are well known in the related art, so a detailed description will be omitted.

Because the kitchen wall 50 is in direct contact with the cryogenic storage fluid, it is exposed to rapid contraction and expansion. The kitchen wall 50 may be damaged due to accumulation of fatigue due to repeated heat shrinkage and thermal expansion, or breakage of the welded portion when heat shrinkage occurs. Because of this problem, the kitchen wall 50 includes a corrugation 51 to have an in-plane stiffness. The corrugated portion 51 is elastically deformed in shape corresponding to the thermal stress, thereby reducing the thermal stress at the welded portion.

The kitchen wall 50 includes first and second wrinkles 51-1 and 51-2 arranged in different directions and an intersection 52 at which the two wrinkles 51 intersect . The thermal stress acting in the in-plane direction of the kitchen wall 50 can be solved by the two-directional wrinkles 51. That is, the thermal stress acting in the longitudinal direction of the first wrinkled portion 51-1 is canceled by the elasticity of the second wrinkled portion 51-2, and the thermal stress acting in the longitudinal direction of the second wrinkled portion 51-2 Can be solved by the stretchability of the first wrinkled portion 51-1.

Although the two-directional wrinkles 51 are vertically arranged in the figure, they may include three or more wrinkles as required. For example, the three corrugations may be arranged at an angle of 60 degrees with respect to each other.

The heat insulating panel assembly includes an insulating panel assembly installed on a plane portion and an insulating panel assembly installed on a corner portion. The corner portion connects the flat portions disposed at different angles and includes a corner portion to which two different heat insulating panels are connected and a vertex portion to which three different heat insulating panels are connected. Hereinafter, the heat insulating panel assembly provided on the flat surface will be described as a basis.

The heat insulating panels 20 and 30 can be generally made of a material having excellent heat insulation performance and light weight such as polyurethane foam (PUF) or reinforced polyurethane foam (R-PUF, Reinforced PUF) It can be kept at an ultra-low temperature state by being insulated from the outside. The heat insulating panel assembly generally has a double insulation structure including the upper heat insulating panel 30 and the lower heat insulating panel 20 for the purpose of improving the heat insulating performance and facilitating the repair.

An inner hull can be used for the outer wall 10 and supports the load of the storage fluid. The lower insulation panel 20 may be fixed to the outer wall 10.

The lower first reinforcing panel 21 can be coupled to the bottom surface so as to be firmly fixed to the outer wall 10. The lower first reinforcing panel 21 can be coupled to the outer wall 10 by various fixing members including the stud bolts 12, 10). ≪ / RTI > The lower first reinforcing panel 21 may be made of plywood or the like and may be attached to the bottom surface of the lower insulating panel 20 using an adhesive such as an epoxy glue or the like.

The insulating panel assembly may include an auxiliary barrier 40 interposed between the upper insulating panel 30 and the lower insulating panel 20. The auxiliary barrier 40 protects the lower insulation panel 20 when the kitchen wall 50 is infiltrated, thereby greatly reducing the time and cost required for the repair.

The auxiliary barrier 40 may be formed of a metal material such as an INVAR, stainless steel or aluminum alloy as in the case of the kitchen wall 50 or a rigid triplex and a support triple triplex) can be used.

The adhesive type manufacturing method and the welding type manufacturing method are used in accordance with the difference in the method of joining the auxiliary barrier 40 to the lower heat insulating panel 20. [ Although not shown in the drawing, in the adhesive type manufacturing method, a rigid triplex is attached by using an adhesive such as epoxy glue on the lower insulating panel 20, and the adjacent rigid triplex is connected with a support triplex, State can be completed. At this time, the shuffle triplex may also be attached to the rigid triplex by an adhesive.

A liquefied gas holding window according to an embodiment of the present invention is a welded manufacturing method in which adjacent auxiliary walls 40 are welded together. The welding method is such that the auxiliary barrier 40 is mechanically coupled instead of bonding to the lower insulating panel 20 and the upper insulating panel 30 is also bonded to the lower insulating panel 20 20).

Hereinafter, a liquefied gas holding window and a method of manufacturing the same according to the first embodiment of the present invention will be described. 1 to 7 are referred to in the following description.

First, the installation process of the lower insulating panel 20 will be described with reference to FIG.

The lower heat insulating panel 20 may be coupled to the outer wall 10 through a lower first reinforcing panel 21 adhered to the bottom surface. The outer wall 10 may be welded with a stud bolt 12 for joining the lower insulating panel 20. Through holes 20a and 21a are formed in the lower heat insulating panel 20 and the lower first reinforcing panel 21 so that the stud bolts 12 can pass therethrough. The diameter of the through hole 21a formed in the lower first reinforcing panel 21 may be smaller than the diameter of the through hole 20a formed in the lower heat insulating panel 20. [

The stud bolt 12 is inserted into the through hole 20a formed in the corner of the lower heat insulating panel 20 and is engaged with the nut and the nut is engaged with the stud bolt 12 to thereby connect the lower first reinforcing panel 21 Restraint. As a result, the lower heat insulating panel 20 to which the lower first reinforcing panel 21 is attached is joined to the outer wall 10. At this time, the foam plug 20b may be inserted into the through hole 20a to maintain the heat insulating performance.

A mastic 11 having an adhesive force and / or a level pad 13 for adjusting a level difference may be interposed between the lower first reinforcing panel 21 and the outer wall 10. In particular, since the mastic 11 has both adhesive force and elasticity, it is possible to combine the outer wall 10 and the lower heat insulating panel 20 and alleviate the impact transmitted to each other.

The plurality of lower insulating panels 20 may be disposed adjacent to each other, and may be arranged in a lattice pattern, for example. The arrangement in the form of a lattice means that the lower insulating panels 20 are disposed not only adjacent to each other in the first direction but also adjacent to each other in the second direction.

And the lower joint 23 can be inserted between the adjacent lower heat insulating panels 20. The lower joint 23 may be a heat insulating material capable of filling a gap between the lower heat insulating panels 20, and a glass wool or the like may be used. The lower joint 23 may be inserted after the lower insulating panel 20 is installed or attached to the side of the lower insulating panel 20.

Next, the process of installing the auxiliary barrier 40 on the lower insulating panel 20 will be described with reference to FIGS. 3 and 4. FIG. Fig. 3 is an exploded perspective view showing a state of engagement of the auxiliary barrier, and Fig. 4 is an enlarged view of Fig.

A lower second reinforcing panel 22 may be laminated on the upper part of the lower insulating panel 20 for installing the auxiliary barrier 40. The lower second reinforcing panel 22 may be made of plywood or the like and may be attached to the lower insulating panel 20 using an adhesive such as an epoxy glue or the like.

An auxiliary barrier connecting member 24 may be provided on the upper part of the lower insulating panel 20. Particularly, when the lower second reinforcing panel 22 is provided, the auxiliary barrier connecting member 24 can be coupled to the upper surface of the lower second reinforcing panel 22. [ The auxiliary barrier connecting member 24 may be made of a metal such as SUS and welded to the auxiliary barrier 40 and may be mechanically coupled to the lower second reinforcing panel 22 by a rivet 24a or the like. The auxiliary barrier connecting member 24 may be received in the groove 22a formed in the lower second reinforcing panel 22 and may not protrude from the upper surface of the lower second reinforcing panel 22. [

In addition, the auxiliary barrier connecting members 24 may be provided in a strip shape and may be arranged in different directions to form intersections. For example, two strips orthogonal to each other. The auxiliary barrier connecting member 24 may be provided parallel to the edge of the opposing lower insulating panel 20. In addition, the auxiliary barrier connecting member 24 may be provided in one strip or may be provided such that a plurality of strips are continuously connected.

A panel fixing unit 25 for fixing the upper insulating panel 30 may be provided on the lower insulating panel 20. In particular, when the lower second reinforcing panel 22 is provided, the panel fixing unit 25 can be coupled to the upper surface of the lower second reinforcing panel 22. [ The panel fixing unit 25 has an engaging portion 25a which is mechanically engaged with the lower second reinforcing panel 22 by means of a rivet or the like and a fixing portion 25b protruding from the upper fixing panel 30, And a protruding member 25b which engages with the protruding member 25b. The panel fixing unit 25 may be received in the groove 22b formed in the lower second reinforcing panel 22 and may not protrude from the upper surface of the lower second reinforcing panel 22. [

The lower insulating panel 20 may have a square shape when viewed from above, and it is preferable that the lower insulating panel 20 is of a weight and size sufficient for the operator to work manually. If the lower insulating panel 20 is large and heavy, it must be operated using mechanical equipment, which increases the cost and time required in the manufacturing process. In the case of the lower heat insulating panel 20, since the mastic 11 is normally attached to the bottom surface of the lower insulating panel 20, the efficiency may be lowered when using mechanical equipment.

For example, the bottom insulating panel 20 according to the embodiment of the present invention may use a reinforced polyurethane foam (R-PUF) having a size of about 1000 mm * 1000 mm, but the weight may be around 20 kg. Therefore, two workers can work manually by using a vacuum gripper or the like.

The auxiliary barrier connecting member 24 is connected (including by being connected by a virtual extension line without being directly connected) with the adjacent auxiliary barrier connecting member 24 to form one closed figure. In Fig. 1, eight lower insulating panels 20 are disposed adjacent to each other, and a rectangular closed shape is formed by the auxiliary barrier connecting member 24 provided on the lower insulating panel 20. As shown in Fig.

One auxiliary barrier 40 sheet constituting the auxiliary barrier 40 may have a shape corresponding to the shape of the closed figure formed by the auxiliary barrier connecting member 24. [ The four corners of the sheet of the auxiliary barrier 40 may be arranged and fixed so as to overlap the auxiliary barrier connecting member 24, respectively. In one example, the sheet of secondary barrier 40 may be secured to the secondary barrier connecting member 24 in a tack welding manner.

At this time, a through hole (40a) through which the projecting member (25b) of the panel fixing unit (25) can penetrate is formed in the seat of the auxiliary barrier (40). After the completion of the installation of the auxiliary barrier 40, the through hole 40a and the panel fixing unit 25 are welded to each other to secure the airtightness of the auxiliary barrier 40. [

After one auxiliary barrier 40 sheet is fixed, another auxiliary barrier 40 sheet may be fixed to the adjacent one side. At this time, one of the four corners of the auxiliary barrier 40 sheet adjacent to the previously installed auxiliary barrier 40 sheet is arranged to overlap with the sheet of the auxiliary barrier wall 40 previously provided, and the other three corners are disposed on the auxiliary barrier connecting member 24 ) And can be fixed. For example, the fixing of the auxiliary barrier 40 sheet and the auxiliary barrier 40 sheet and the securing of the auxiliary barrier 40 sheet and the auxiliary barrier connection member 24 can be performed using a tack welding method.

The above installation process is continuously performed to fix all the sheets of the auxiliary barrier 40 on the lower insulating panel 20. [ However, since it is still in a state of being in a state of being in contact with the gap between the adjoining auxiliary barrier 40 sheets, it is necessary to perform the main welding in order to maintain airtightness.

Both edges of the sheets of the auxiliary barrier wall 40 adjacent to each other are welded by lap welding or butt welding, thereby ensuring airtightness. As the welding method which can be used at this time, various welding methods used in the related art can be used. An automatic welding apparatus using laser welding or plasma welding may also be used to improve uniformity of work quality while improving welding quality. Above-mentioned lap welding, butt welding, laser welding, plasma welding, etc. are well known in the related art, so a detailed description will be omitted.

On the other hand, the auxiliary barrier connecting member 24 can be prevented from being deformed by the welding heat due to the welding heat (or welding seam) when the adjacent auxiliary barrier walls 40 are welded to each other . It is possible to prevent deformation of the auxiliary barrier 40 sheet, which may be caused by high temperature, particularly when plasma welding is used. At this time, in the process of overlap welding or butt welding of the sheets of the auxiliary barrier 40, the welding heat is transmitted to the auxiliary barrier connecting member 24, and the auxiliary barrier connecting member 24 and the auxiliary barrier 40, The sheets may be welded together.

Since the upper barrier panel 40 is located between the upper insulating panel 30 and the storage fluid, a certain amount of thermal deformation can not be avoided even if the thermal barrier is not greatly generated as the main wall 50. In the case of the adhesive type manufacturing method in which the auxiliary barrier and the lower insulating panel are bonded by bonding, stress is applied to the bonding surface with the lower insulating panel due to shrinkage and expansion of the auxiliary barrier.

The secondary barrier 40 may include a corrugation 41 to have an in-plane stiffness. The corrugated portion 41 is elastically deformed in shape corresponding to the thermal stress, thereby reducing the thermal stress at the welded portion.

The auxiliary barrier 40 includes first and second wrinkled portions 41-1 and 41-2 arranged in different directions and an intersection portion 42 where the two wrinkled portions 41 intersect with each other . The thermal stress acting in the in-plane direction of the auxiliary barrier 40 can be relieved by the two-directional folds 41. [ That is, the thermal stress acting in the longitudinal direction of the first wrinkled portion 41-1 is canceled by the elasticity of the second wrinkled portion 41-2, and the thermal stress acting in the longitudinal direction of the second wrinkled portion 41-2 Can be solved by the stretchability of the first wrinkled portion 411-.

Although the two-sided wrinkle portions 41 are shown vertically, they may include three or more wrinkles as required. For example, the three corrugations may be arranged at an angle of 60 degrees with respect to each other.

The corrugated portion 41 provided on the auxiliary barrier 40 may be convexly protruded in the direction in which the upper insulating panel 30 is installed and may be located at the boundary between the two adjacent lower insulating panels 20. [ Further, the position of the corrugated portion 40 is not limited to being located at the boundary of the lower heat insulating panel 20. [ So that it can be positioned across the lower insulating panel 20.

On the other hand, the figure shows that the interval (pitch) between the corrugated portions 51 of the kitchen wall 50 and the interval between the corrugated portions 41 of the auxiliary wall 40 are constant. However, the spacing between the corrugations 41 of the auxiliary barrier 40 is generally greater than the spacing between the corrugations 51 of the main wall 50. This is because a larger thermal stress acts on the kitchen wall 50 in direct contact with the cryogenic liquefied gas, so that the wrinkles 51 for eliminating thermal stress must be provided at a shorter distance. In comparison, the auxiliary barrier 40 is insulated by the upper insulating panel 30, and thus receives a smaller thermal stress than the main wall 50. Therefore, the interval between the corrugations 41 of the auxiliary barrier 40 can be wide. However, the spacing between the corrugations of the barrier may vary depending on the material and thickness of the barrier.

The auxiliary barrier 40 sheet may be provided so as to extend across the plurality of lower insulating panels 20. [ The meaning of being laid over the lower insulating panel 20 includes the case of completely covering and the case of covering only partly. In Fig. 3, it is shown that one auxiliary barrier 40 sheet is provided over eight lower insulating panels 20.

On the other hand, the edge of the sheet of the auxiliary barrier 40 is seated so as to deviate from the center of the lower insulating panel 20. The edge of the auxiliary barrier 40 sheet is required to be fixed to the panel fixing unit 25 located at the center of the lower insulating panel 20 because it must be welded to the edge of the auxiliary barrier connecting member 24 and / In order to prevent overlapping. It has been described above that the interference between the auxiliary barrier 40 sheet and the panel fixing unit 25 can be prevented by forming the through hole 40a through which the projecting member 25b penetrates the auxiliary barrier 40 sheet.

The length L of one side of the auxiliary barrier 40 sheet is smaller than the number n of the lower insulating panel 20 by subtracting one from the number n of the bottom insulating panels 20 covered by the auxiliary barrier 40 sheet. The length D of the one side of the light-emitting diode D may be slightly larger or smaller than the product of the length D of one side of the light- The length L of the precise sides of the secondary barrier 40 sheet can be determined by the distance spaced between adjacent lower insulating panels 20 and the spacing that overlaps when the secondary barrier 40 sheets are welded together. In the drawing, when the length of one side of the lower insulating panel 20 is a, the length of the longer side of the auxiliary barrier 40 is slightly larger than 3a and the length of the smaller side is slightly larger than a.

The panel fixing unit 25 is positioned at the center of the lower heat insulating panel 20 and the auxiliary wall connecting member 24 is positioned parallel to the edge of the lower heat insulating panel 20, And that the auxiliary barrier 40 is provided in a shape corresponding to the closed figure of the auxiliary barrier connecting member 24 formed by connecting the plurality of the bottom insulating panels 20 And the auxiliary barrier 40 are provided with the through holes 40a through which the projecting members 25b of the panel fixing unit 25 can penetrate.

The lower first reinforcing panel 21 and the lower second reinforcing panel 22 are stacked and the plurality of lower heat insulating panels 20 having the auxiliary wall connecting member 24 and the panel fixing unit 25 are installed, It is possible to arrange the auxiliary barrier ribs 40 on the outer wall 10 by fixing the plurality of auxiliary barrier ribs 40 to the auxiliary barrier rib connecting member 24 and welding the sheets of the auxiliary barrier 40 to each other, It becomes. At this time, the auxiliary barriers 40 can be manufactured in the same manner as the sheets provided in the same shape.

The main welding of the auxiliary barrier 40 sheet and the auxiliary barrier 40 sheet can use an automatic welding device. In particular, welding of the corrugations of the auxiliary barrier 40 can also be performed using an automatic welding apparatus. At this time, in order to manually weld the worker to weld the sheets of the auxiliary barrier 40 and the auxiliary barrier 40 of thin thickness, or to use the automatic welding apparatus, Fit-Up. In particular, the use of automatic welding equipment is important to the work of the foot.

Up work may be performed by a fit-up zig (not shown) fixedly installed on the lower insulating panel 20. [ Up jig can be fixed to the auxiliary barrier 40 sheet by being engaged with the protruding member 25b protruding to the panel fixing unit 25 or by a suction type.

The worker can close the sheets of the auxiliary barrier 40 by pressing the sheet of the auxiliary barrier 40 covering the upper part with the use of the pick-up jig or by raising the sheet of the auxiliary barrier 40 which is placed below. At this time, in order to raise the sheet of the auxiliary barrier wall 40 placed below, an adsorption method and a bonding method can be used.

Usually, after the sheet of the auxiliary barrier 40 is wiped, the abutting is performed to fix the sheets of the auxiliary barrier 40 to each other. The sheets of auxiliary barrier 40 secured to each other are easily weldable by automatic welding equipment. In particular, in the case of a wrinkle portion including a curved portion, a sophisticated work of finishing is required in order to improve the welding quality by the automatic welding device.

The automatic welding apparatus performs welding while moving along a rail which is fixed to the lower insulating panel 20. [ Therefore, in order to use the automatic welding device, it is necessary to fix the rail around the welding line.

In the method of manufacturing the liquefied gas holding window according to the embodiment of the present invention, the rails can be fixedly installed using the panel fixing unit 25 for fixing the lower insulating panel 20 and the upper insulating panel 30. It has been described that the protruding member 25b protruding for fixing the upper insulating panel 30 to the panel fixing unit 25 may be provided. The rails of the automatic welding apparatus may be fixedly coupled to the protruding members 25b of the panel fixing unit 25 and may be coupled to other shapes of coupling members (not shown) provided separately to the panel fixing unit 25 .

4, a panel fixing unit 25 is provided at the center of the lower insulation panel 20, and an auxiliary barrier connection member 24 may be provided at the side of the panel fixing unit 25. As shown in FIG. On the other hand, unlike the drawing, the auxiliary barrier connecting member 24 and the panel fixing unit 25 may be in contact without being separated from each other.

Next, a method of welding the sheet of the auxiliary barrier 40 using the automatic welding apparatus will be described.

It has been described that the sheet of the auxiliary barrier 40 is previously contacted to the auxiliary barrier connecting member 24 and the adjoining auxiliary barrier 40 sheets are contacted and fixed to each other. Now, by performing the main weld along a line (weld line) where the sheets of the two auxiliary walls 40 overlap or abut, the installation of the auxiliary barrier is completed. A rail can be installed near the weld line so that the automatic welding device can move along the weld line. In this case, when the rail and the weld line are provided in parallel, the welding quality can be improved and the working time can be shortened.

The rails can be fixed to a plurality of panel fixing units 25 arranged in one direction and installed parallel to the weld line. At this time, since the panel fixing unit 25 and the auxiliary barrier connecting member 24 are disposed adjacent to each other, the automatic welding apparatus installed on the rails can facilitate welding work along the weld line. After the automatic welding is completed, the rails are disassembled from the panel fixing unit 25.

The through hole 40a is formed so that the projecting member 25b of the panel fixing unit 25 penetrates through the sheet of the auxiliary barrier 40, as described above. In order to ensure the airtightness of the auxiliary barrier 40, the edge of the hole formed in the sheet of the auxiliary barrier 40 is welded to the panel fixing unit 25, and arc welding may be performed along the shape of the through hole 40a.

When welding of the auxiliary barrier 40 is completed, it is checked whether the airtightness is secured. As the inspection process, a method of injecting a test gas between the auxiliary barrier 40 and the lower insulating panel 20 and checking whether the test gas leaks to the outside can be used. If the inspection gas is detected from the outside as an inspection result, it is judged that the welding condition of the part is defective and re-welding is performed. On the other hand, if it is determined that the airtightness is ensured, the process for installing the upper insulating panel 30 proceeds to the next step.

Next, the process of installing the upper insulating panel 30 will be described with reference to FIGS. 5 and 6. FIG. Fig. 5 is an exploded perspective view showing a state in which the upper insulating panel is joined, and Fig. 6 is an enlarged view of Fig. 2 showing an upper insulating panel according to the first embodiment of the present invention.

The plurality of upper insulating panels 30 may be disposed adjacent to each other, and may be arranged in a lattice pattern, for example. It is meant that the upper insulating panels 30 are disposed adjacent to each other in the second direction as well as disposed adjacent to each other in the first direction.

An upper joint 33 may be inserted between the adjacent upper heat insulating panels 12. The upper joint 33 may be a thermal insulation material capable of filling a gap between the upper insulating panels 30, and a glass wool or the like may be used. The upper joint 33 may be installed after the upper insulating panel 30 is installed or attached to the side of the upper insulating panel 30.

If the distance between the lower insulating panels 20 is neglected (generally very narrow), the upper insulating panel 30 may be provided in an approximately multiples of the size of the lower insulating panel 20. In this case, the edge of the upper insulating panel 30 is aligned with the boundary between the lower insulating panels 20. Accordingly, the upper insulating panel 30 can be installed in a manner similar to the installation process of the lower insulating panel 20, thereby enhancing the convenience of manufacture.

If the corner of the upper heat insulating panel 30 does not coincide with the boundary of the lower heat insulating panel 20 but is staggered with the lower heat insulating panel 20, the upper heat insulating panel 30 is fixed to the lower heat insulating panel 20 A connecting panel (not shown) must be inserted into the gap between the upper insulating panels 30, and at this time, the connecting panel is fixed by bonding, which is inconvenient to manufacture.

The upper first reinforcing panel 31 may be coupled to the bottom surface so that the upper insulating panel 30 can be firmly fixed to the lower heat insulating panel 20. [ The upper first reinforcing panel 31 may be made of plywood or the like and attached to the bottom surface of the upper insulating panel 30 using an adhesive such as epoxy glue.

The upper insulating panel 30 and the upper first reinforcing panel 31 are formed with through holes 30a and 31a so that the projecting members 25b can pass through. The diameter of the through hole 31a formed in the upper first reinforcing panel 31 may be smaller than the diameter of the through hole 30a formed in the upper insulating panel 30.

The diameter of the through hole 31a formed in the upper first reinforcing panel 31 may be the same as the diameter of the protruding member 25b. The upper first reinforcing panel 31 is prevented from moving relative to the projecting member 25b.

The protruding member 25b is inserted into the through hole 30a formed at the center of the upper heat insulating panel 30 and joined with the nut and the nut is engaged with the protruding member 25b to form the upper first reinforcing panel 31 ). As a result, the upper heat insulating panel 30 to which the upper first reinforcing panel 31 is attached is joined to the lower heat insulating panel 20. At this time, the foam plug 30b may be inserted into the through hole 30a to maintain the heat insulating performance.

The upper insulating panel 30 may be provided in a size and shape corresponding to the area where the two lower insulating panels 20 are disposed adjacent to each other. For example, when the lower insulation panel 20 having a square (1 X 1) as viewed from above is provided as shown in the drawing, the upper insulation panel 30 has a rectangular shape having two sides of one side, (1 x 2). It is a matter of course that the ratio of the shape and length of the specific heat insulating panels 20 and 30 may be varied depending on the case.

The upper insulating panel 30 may be joined by one lower fixing panel 20 and one panel fixing unit 25 located at the center of the lower insulating panel 20. In this case, two panel fixing units 25 may be coupled to one upper insulating panel 30. By providing two fixing points on the upper heat insulating panel 30, rotation of the upper heat insulating panel is prevented.

If the shape and size of the upper insulating panel 30 are the same as those of the lower insulating panel 20 or the like, unlike the drawings, The upper and lower thermal insulation panels 30 and 20 are fixed to each other. However, in this case, the upper insulating panel 30 is allowed to rotate on the lower insulating panel 20.

If rotation of the upper insulating panel 30 is allowed, inconvenience may be caused in the manufacturing process. In particular, when the upper insulating panel 30 is installed on the side surface or the ceiling, the upper insulating panel 30 may rotate unintentionally, which may take time and effort to align them. Also, since the upper insulating panel 30 is allowed to rotate, stress may be generated between the adjacent upper heat insulating panels 30, thereby reducing the durability of the cargo window. Further, stress is concentrated on the main wall 20 fixed to the upper heat insulating panel 30, which may cause damage to the welded portion or the like.

In the above description, two or more lower heat insulating panels 20 are coupled to one upper heat insulating panel 30 to prevent rotation of the upper heat insulating panel 30. Alternatively, one upper insulating panel 30 And one lower insulating panel 20 are combined and a plurality of panel fixing units 25 are provided.

An upper second reinforcing panel 32 may be laminated on the top of the upper insulating panel 30 for installing the kitchen wall 50. The upper second reinforcing panel 32 may be made of plywood or the like and may be attached to the upper insulating panel 30 using an adhesive such as an epoxy glue or the like.

The upper wall of the upper insulating panel 12 may be provided with a kitchen wall connecting member 34. In particular, when the upper second reinforcing panel 32 is provided, the main body wall connecting member 34 can be coupled to the upper surface of the upper second reinforcing panel 32. The kitchen wall connecting member 34 is made of a metal such as SUS and can be welded to the kitchen wall 50 and mechanically coupled to the upper second reinforcing panel 32 by a rivet 34a or the like. The main body wall connecting member 34 may be received in the groove 32a formed in the upper second reinforcing panel 32 and may not protrude from the upper surface of the upper second reinforcing panel 32. [

In addition, the kitchen wall connecting members 34 may be provided in a strip shape and may be arranged in different directions to form intersections. For example, two strips orthogonal to each other. The kitchen wall connecting member 34 may be provided parallel to the edge of the facing upper insulating panel 30. In addition, the kitchen wall connecting member 34 may be provided in one strip or may be provided so that a plurality of strips are continuously connected.

A barrier wall member 35 for installing the kitchen wall 50 may be provided on the upper portion of the upper insulating panel 30. In particular, when the kitchen wall connecting member 34 is provided, the wall mounting member 35 may be provided on the upper portion of the kitchen wall connecting member 34.

It has been described above that a rail is to be installed for welding the seat of the secondary barrier 40 by using the automatic welding apparatus and a rail is provided for the panel fixing unit 25. [ Similarly, in order to weld a sheet of the kitchen wall 50 using an automatic welding apparatus, a barrier mounting member 35 capable of mounting a rail is required.

The barrier mounting member 35 (see FIG. 5) may be a stud bolt provided at the intersection where the two-directional main body wall connecting members 34 are perpendicular to each other. The barrier mounting member 35 may be welded on the wall wall connecting member 34. [ The intersection where the two-way wall wall connecting member 34 provided with the barrier mounting member 35 meets may be a four-sheet intersection where four sheets of the kitchen wall 50 meet. The four sheets of the kitchen wall 50 may be welded around the barrier mounting member 35 when it is chamfered at the corner of the sheet of the kitchen wall 50 and may not interfere with the barrier mounting member 35. At this time, the corner portion of the seat of the kitchen wall 50 should be welded to the kitchen wall connecting member 34 to maintain airtightness.

The barrier mounting member 35 is for mounting the kitchen wall 50 and can be removed when the installation of the kitchen wall 50 is completed. This is because the operator can be treated as an obstacle when moving.

Next, the process of installing the kitchen wall 50 will be described with reference to FIG. Fig. 7 is a perspective view showing a state of engagement of the kitchen wall. Fig.

The main body wall connecting member 34 is connected to the adjacent main body wall connecting member 34 (including those connected by a virtual extension line without being directly connected thereto) to form one closed figure. In Fig. 1, four upper insulating panels 30 are arranged adjacent to each other, and a rectangular shaped closed figure is formed by a main body wall connecting member 34 provided on the upper insulating panel 30. In Fig.

One sheet of the kitchen wall 50 constituting the kitchen wall 50 may be in a shape corresponding to the shape of the closed figure formed by the kitchen wall connecting member 34, The four corners may be disposed and fixed so as to overlap with the respective wall wall connecting members 34, respectively. In one example, the seat of the kitchen wall 50 may be fixed to the kitchen wall connecting member 34 in a tack welding manner.

After one sheet of the kitchen wall 50 is fixed, another sheet of the kitchen wall 50 can be fixed to the adjacent one side. At this time, one corner of the four corners of the kitchen wall 50 sheet adjoining to the pre-installed kitchen wall 50 sheet is arranged to overlap with the pre-installed kitchen wall 50 sheet and the other three corners are connected to the kitchen wall connecting member 34 ) And can be fixed. The fixing of the seat of the kitchen wall 50 and the fixing of the seat of the kitchen wall 50 and the fixing of the seat wall and the kitchen wall connecting member 34 of the kitchen wall 50 may use a tack welding method.

The above installation process is continuously performed to fix all the sheets of the kitchen wall 50 on the upper heat insulating panel 30. [ However, since it is still in a state of being in contact with the gap between adjacent sheets of the kitchen wall 50, it is necessary to perform this welding in order to maintain airtightness.

Both edges of the adjacent sheet of the kitchen wall 50 are welded by lap welding or butt welding, thereby ensuring airtightness. As a welding method that can be used at this time, a method used for welding the auxiliary barrier can be used, and of course, an automatic welding device can be used.

On the other hand, the kitchen wall connecting member 34 is located below the welding line (or welding seam) when the adjacent sheets of the kitchen wall 50 are welded together, thereby preventing the sheet of the kitchen wall 50 from being deformed by the welding heat . It is possible to prevent deformation of the sheet of the kitchen wall 50, which may be caused by high temperature, particularly when plasma welding is used. At this time, in the process of overlap welding or butt welding of the sheets of the kitchen wall 50, the welding heat is transmitted to the kitchen wall connecting member 34 to connect the lower kitchen wall connecting member 34 and the kitchen wall 50 located thereon, The sheets may be welded together.

The main welding of the kitchen wall 50 sheet and the kitchen wall 50 sheet can utilize automatic welding equipment. In particular, welding of the corrugated portion of the kitchen wall 50 can also use an automatic welding apparatus. At this time, in order to manually weld the worker to weld the sheet of the kitchen wall 50 and the sheet of the kitchen wall 50 with a thin thickness or to use the automatic welding apparatus, Fit-Up. In particular, the use of automatic welding equipment is important to the work of the foot.

Since the same method as the process of installing the auxiliary barrier 40 can be used for the work of the fatigue, a detailed description will be omitted. The pick-up jig (not shown) may be fixed to the sheet of the kitchen wall 50 by being engaged with or adsorbing to the barrier-attaching member 35 provided on the kitchen wall connecting member 34.

The automatic welding apparatus performs welding while moving along the rails that are installed to be fixed to the upper insulating panel (30). Therefore, in order to use the automatic welding device, it is necessary to fix the rail around the welding line.

In the method of manufacturing the liquefied gas holding window according to the embodiment of the present invention, the rails can be fixed by using a barrier member 35 (for example, a stud bolt) provided on the main body wall connecting member 34.

Next, a method of welding the sheet of the kitchen wall 50 using the automatic welding apparatus will be described.

It has been described that the seat of the kitchen wall 50 is previously touched to the kitchen wall connecting member 34 and the adjacent sheets of the kitchen wall 50 are contacted and fixed to each other. Now, when the main welding is performed along the line (weld line) where the two kitchen wall 50 sheets overlap or abut, the installation of the kitchen wall is completed. A rail can be installed near the weld line so that the automatic welding device can move along the weld line. In this case, when the rail and the weld line are provided in parallel, the welding quality can be improved and the working time can be shortened.

The rails are fixed to a plurality of barrier mounting members 35 arranged in one direction so as to be parallel to the welding line, so that the automatic welding apparatus installed on the rails can facilitate welding along the welding line. After the automatic welding is completed, the rails are disassembled from the barrier mounting member 35.

When the welding of the kitchen wall 50 is completed, it is checked whether the airtightness is secured. As the inspection process, a method of injecting a test gas between the kitchen wall 50 and the upper heat insulating panel 30 and checking whether the test gas leaks to the outside can be used. If the inspection gas is detected from the outside as an inspection result, it is judged that the welding condition of the part is defective and re-welding is performed.

6 to 10, an upper insulating panel structure according to an embodiment of the present invention will be described. FIG. 6 is an upper side heat insulating panel structure according to a first embodiment of the present invention, FIG. 8 is an upper insulating panel structure according to a second embodiment of the present invention, FIG. 9 is a top insulating panel structure according to the third embodiment of the present invention, Fig. 10 is an enlarged view of Fig. 2 showing an upper insulating panel structure according to a fourth embodiment of the present invention. Fig.

The corrugated portion 41 of the auxiliary barrier 40 protrudes toward the direction in which the upper heat insulating panel 30 is installed. It is preferable to form a groove for accommodating the corrugated portion 41 at the bottom of the upper insulating panel 30 in order to avoid interference between the upper insulating panel 30 and the corrugation 41 of the auxiliary barrier 40 Separate processing is required.

When grooving the upper insulating panel 30, the sloshing load applied to the upper insulating panel 30 should be considered.

Sloshing is a phenomenon in which a liquid substance contained in a cargo hold flows when a ship or floating structure moves in various sea states. If there is liquid in only a part of the interior of the cargo hold, the wall and the ceiling of the cargo hold will be severely impacted by the sloshing caused by the flow of the liquid, which is called sloshing impact. The sloshing phenomenon is necessarily caused by the dynamic movement of the ship during the operation of the ship, and the cargo hold is to be designed to have sufficient strength to withstand the load by sloshing.

However, when grooves are formed on the bottom surface of the integrally formed upper insulating panel 30, the stress transmitted from the upper portion due to the sloshing impact may concentrate on the grooves, resulting in cracks in the grooves in which fatigue is accumulated continuously The upper insulating panel 30 may be damaged.

The upper insulating panel structure according to the embodiment of the present invention may include an upper first insulating panel 30 and an upper second insulating panel 60. [ The upper first thermal insulation panel 30 has a relatively large thickness and is intended for insulation. The upper first thermal insulation panel 30 has the same reference numerals as those of the upper thermal insulation panel 30 and can be replaced with the description of the upper insulation panel 30 described above.

An upper first reinforcing panel 31 may be interposed between the first upper heat insulating panel 30 and the second upper heat insulating panel 60. The upper first reinforcing panel 31 serves to fix the upper first thermal insulating panel 30 to the lower thermal insulating panel 20 and at the same time the upper first thermal insulating panel 30 and the upper second thermal insulating panel 60 are physically And serves as a breakwater to prevent the sloshing impact, which is transmitted past the upper first thermal insulation panel 30, from being transmitted to the upper second thermal insulation panel 60.

The upper second thermal insulation panel 60 includes a receiving groove 61 and a space for accommodating the corrugation 41 of the auxiliary barrier 40. The upper second thermal insulation panel 60 is formed of a heat insulating material Performance can be ensured. The upper second thermal insulation panel 60 may be provided as a heat insulation pad similar to the upper first thermal insulation panel 30. [ That is, polyurethane foam or reinforced polyurethane foam may be used. Considering that the receiving groove 61 is formed in the upper second heat insulating panel 60, rigidity can be secured by using a reinforced polyurethane foam.

As described above, in the liquefied gas holding window according to the embodiment of the present invention, the upper heat insulating panel structure is divided into the upper first heat insulating panel 30 and the upper second heat insulating panel 60, It is possible to accommodate the corrugated portion 41 of the auxiliary barrier 40 by interposing the panel 31 and to secure the rigidity of the upper first thermal insulation panel 30 and to overcome the damage caused by the sloshing load.

Further, even when the upper second thermal insulation panel 60 is broken due to the processing of the receiving groove 61, the length through which the cracks are conducted is not large, so that the rigidity of the entire liquefied gas holding window is not affected. Even if repair is required, it can be repaired at a relatively low cost.

The receiving groove 61 of the upper second heat insulating panel 60 shown in FIG. 6 is provided to be spaced apart from the corrugation 41 of the auxiliary barrier 40. That is, a buffer space is formed between the upper second thermal insulation panel 60 and the corrugation 41. It is possible to prevent the shape of the corrugated portion 41 from being changed because it is not in contact with the corrugated portion 41 of the auxiliary wall 40 even when the shape of the upper second thermal insulating panel 60 is changed .

The upper second thermal insulation panel 60 is formed with a through hole 62 through which the projecting member 25b of the panel fixing unit 25 passes. At this time, the diameter of the through hole 62 formed in the upper second thermal insulation panel 60 and the diameter of the through hole 31a formed in the upper first reinforcing panel 31 may be equal to each other.

The stress acting on the upper first reinforcing panel 31 is concentrated in the through hole 31a. The diameter of the through hole 62 formed in the upper second heat insulating panel 60 is smaller and the upper second thermal insulating panel 60 is exposed to the inner diameter of the through hole 31a of the upper first reinforcing panel 31 The upper second heat insulating panel 60 may be damaged due to the stress acting on the edge of the through hole 31a of the upper first reinforcing panel 31. [ On the other hand, when the diameter of the through hole 62 formed in the upper second heat insulating panel 60 is larger, by the stress acting on the edge of the through hole 31a of the upper first reinforcing panel 31, The edge of the through hole 62 of the panel 60 is pressed, so that breakage may also occur.

In contrast, in the embodiment of the present invention, by making the diameters of the two through holes 31a and 62 the same, it is possible to minimize damage caused by stress acting on the edge portion of the through hole 31a.

It has been described above that the secondary barrier 40 can undergo thermal contraction or thermal expansion. Therefore, a friction reducing member (not shown) may be provided at a portion of the auxiliary barrier 40 contacting the planar portion to reduce the frictional force between the upper second thermal insulation panel 60 and the auxiliary barrier 40. The friction reducing member may be a film adhered to the bottom surface of the upper second heat insulating panel 60.

An impact absorbing member (not shown) capable of absorbing impact transmitted to the auxiliary barrier 40 may be provided on the bottom surface of the upper second thermal insulation panel 60. In particular, the shock absorbing member can absorb the sloshing shock transmitted from the upper second insulating panel 60 to the auxiliary barrier 40.

The receiving groove 61-1 of the upper second heat insulating panel 60-1 shown in FIG. 8 is provided so as to be in close contact with the corrugated portion 41 of the auxiliary barrier 40. As shown in FIG. Therefore, the auxiliary barrier 40 can serve as a reinforcing member of the upper second heat insulating panel 60-1. The corrugated portion 41 of the auxiliary barrier 40 can be formed on the inner surface of the receiving groove 61-1 by supporting the inner surface of the receiving groove 61-1 of the upper second heat insulating panel 60-1 Cracks can be prevented.

As shown in Fig. 9, the upper second thermal insulation panel 60-2 may include a penetration portion 63 connected to the receiving groove 61-2. The penetrating portion 63 can relieve the stress accumulated in the upper second heat insulating panel 60-2 by allowing the stress to be directly transmitted to the corrugated portion 41 of the secondary barrier 40. [

At this time, the penetrating portion 63 may be positioned vertically to correspond to the floor of the corrugation 41 of the auxiliary barrier 40. The thickness of the upper second thermal insulation panel 60-2 is the smallest in the valleys of the receiving grooves 61-2 and therefore the possibility of breakage in the upper second thermal insulation panel 60-2 It is the largest. The upper second thermal insulation panel 60-2 according to the embodiment of the present invention can eliminate the concentration of stress by forming the penetrating portion 63 in advance at a place where a crack is expected.

The penetration portion 63 may be a cut-out portion for cutting the upper second thermal insulation panel 60-2. The stress that may accumulate between the penetrating portion 63 and the adjacent penetrating portion 63 when the upper second heat insulating panel 60-2 is cut off can be eliminated. However, when the incision portion is increased, the time required for constructing and installing the upper second thermal insulation panel 60-2 may increase, so that the position and number of the incision portion can be selected in consideration of stress concentration and manufacturing convenience .

The liquefied gas holding window according to the fourth embodiment of the present invention shown in FIG. 10 may further include a spacer 64 provided between the auxiliary barrier 40 and the upper first reinforcing panel 31. The spacer 64 may be made of a material having a higher rigidity than the upper second heat insulating panel 60 to maintain a distance between the upper first reinforcing panel 31 and the flat portion of the auxiliary barrier 40. Therefore, the stress applied to the upper second heat insulating panel 60 can be reduced.

The spacer 64 may be provided to receive the protruding member 25b of the panel fixing unit 25, and may be provided in a cylindrical shape, for example. The stress is concentrated on the edge of the through hole 31a of the upper first reinforcing panel 31 in advance. The spacer 64 can relieve the stress transmitted to the edge portion by supporting the periphery of the through hole 31a of the upper first reinforcing panel 31. [

Further, the spacer 64 can be seated and supported on the engaging member 25a of the panel fixing unit 25. [ Since the spacer 64 has rigidity, it transmits stress rather than reducing the stress. At this time, since the engaging member 25a is provided under the spacer 64, the stress transmitted through the spacer 64 can be dispersed to an area as wide as the width of the engaging member 25a.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, You will understand. Accordingly, the true scope of the invention should be determined only by the appended claims.

10: outer wall, 11: mastic,
12: Stud bolt, 13: Level pad
20: lower insulation panel, 20a: through hole,
20b: foam plug, 21: lower first reinforcing panel,
21a: Through hole, 22: Lower second reinforcing panel,
22a, 22b: groove, 23: lower joint,
24: auxiliary barrier connecting member, 24a: rivet,
25: a panel fixing unit, 25a: a coupling portion,
25b: protruding member, 30: upper first heat insulating panel,
30b: foam plug, 31: upper first reinforcing panel,
32: upper second reinforcing panel, 33: upper joint,
34: Kitchen wall connecting member, 35: Barrier mounting member,
40: auxiliary barrier, 40a: hole,
41: wrinkle portion, 42: intersection portion,
50: a kitchen wall, 51: a wrinkle portion,
52: intersection, 60: upper second insulation panel,
61: receiving groove, 62: penetrating hole,
63: penetrating portion, 64: spacer.

Claims (11)

A liquefied gas cargo hold comprising a heat insulating panel assembly surrounding a main wall surrounding an accommodating space of the liquefied gas and insulated from the outside by the liquefied gas,
The heat insulating panel assembly includes:
A lower heat insulating panel installed on the outer wall;
An auxiliary barrier provided on the lower heat insulating panel to seal the lower heat insulating panel and including a flat portion and a convex wrinkle portion in a direction in which the kitchen wall is installed;
An upper insulating panel laminated on the auxiliary barrier; And
And a panel fixing unit installed on the lower heat insulating panel to fix the upper heat insulating panel,
The upper insulating panel
An upper reinforcing panel provided at a lower portion of the upper first heat insulating panel and coupled to the panel fixing unit; a lower portion provided at a lower portion of the upper reinforcing panel, the lower portion being seated on a flat portion of the auxiliary wall; And an upper second heat insulating panel provided with a receiving groove capable of receiving the corrugation of the barrier wall. The method according to claim 1,
Wherein the flat portion of the auxiliary barrier supports the upper insulating panel,
Wherein the receiving groove of the upper insulating panel is spaced apart from the corrugation of the auxiliary barrier so that a buffer space is formed between the corrugation of the auxiliary barrier and the upper insulating panel. The method according to claim 1,
The inner side surface shape of the receiving groove of the upper heat insulating panel corresponds to the outer side surface shape of the corrugated portion of the auxiliary wall,
And the inner side surface of the receiving groove of the upper insulating panel is provided to be in contact with the corrugation of the auxiliary barrier. delete 4. The method according to any one of claims 1 to 3,
Wherein the pleats comprise a first pleat portion arranged in a first direction, a second pleat portion arranged in a second direction different from the first direction, and an intersection where the first pleat portion and the second pleat portion intersect,
Wherein the receiving groove includes a first receiving groove for receiving the first wrinkle portion, a second receiving groove for receiving the second wrinkle portion, and a second receiving groove for receiving the intersecting portion, Liquefied gas holdings including receiving grooves. The method according to claim 1,
Wherein the upper first insulation panel, the upper reinforcement panel, and the upper second insulation panel have the same width direction shape. The method according to claim 1,
Wherein the upper reinforcing panel and the upper second insulating panel include through holes through which protruding members of the panel fixing unit pass, the upper first insulating panel including through holes for receiving the projecting members,
And the diameter of the through hole of the upper first heat insulating panel is larger than the diameter of the through hole of the reinforcing panel. 8. The method of claim 7,
And the diameter of the through hole of the reinforcing panel and the diameter of the through hole of the upper second heat insulating panel are the same. The method according to claim 1,
And the upper second heat insulating panel includes a penetrating portion connected to the receiving groove. 10. The method of claim 9,
And the penetrating portion is positioned vertically so as to correspond to a floor of the auxiliary barrier rib portion. 10. The method of claim 9,
And the penetrating portion cuts the upper second heat insulating panel.

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