KR20170113467A - Thermally insulating edge block for the manufacture of a tank wall - Google Patents

Abstract

A sealing and adiabatic tank constituting a load-bearing structure, said tank comprising a plurality of tank walls (5, 6) comprising an insulating barrier and a sealing membrane, said first load-bearing wall (1) , 4 and a row of adiabatic edge blocks (9) located along the edges (2, 4) of the tank comprises a fixing strip (32) parallel to the edge (4) Both ends of the strip 32 each include a tab 33 protruding to the individual side of the edge block 9 and the tab 33 is fixed to an anchor rod (not shown) fixed to the second load- 43 to transmit tension between the securing strip 32 of the edge block 9 and the second load bearing walls 1, 3.

Description

{THERMALLY INSULATING EDGE BLOCK FOR THE MANUFACTURE OF A TANK WALL}

The present invention relates to the field of sealed thermal insulation tanks. In particular, the present invention relates to the transport of liquid petroleum gas (also known as LPG) in enclosed adiabatic tanks, for example, at temperatures between -50 ° C and 0 ° C, in connection with the storage or transport of liquids at low temperatures Such as tanks of ships for transporting liquefied natural gas (LNG) at about-162 ° C at atmospheric pressure.

Methane tankers are known, for example, in FR 3008765. This document describes a methane tanker tank comprising a plurality of longitudinal tank walls and a plurality of transverse tank walls. Each wall of the tank includes a double sealing membrane with a thermally insulated double barrier inserted therein.

When the liquefied gas is loaded and unloated, the change in temperature causes a major thermal deformation, thus stressing the sealing membrane of the tank. Likewise, transport by the sea movement of the liquefied gas in the tank also exerts a great force on the insulating barrier and the membrane of the tank. According to document FR3008765, the sealing membrane of the tank is anchored to the load bearing structure using anchor couplings in the area where the longitudinal walls join with the walls in the width direction, to prevent the sealing properties of the tank from deteriorating. The sealing membranes are connected to the coupling by composite beams attached to the inner surface of the heat-insulating boxes forming the insulating barrier.

In addition, it is known to seal an adiabatic tank with walls made using modular components arranged in a repeating pattern over a large surface area. However, there are special zones within tanks whose configuration must be changed due to the presence of special items of tank equipment. For example, FR3023257 teaches a tank bottom wall with a sump inserted.

The concept underlying the present invention is the concept of absorbing the tensile force in the sealing membrane through a coupling anchored to a loadbearing structure without applying a main shear stress to the elements forming the insulating barrier.

Another concept underlying the present invention is to locally modify the structure of the tank wall near a particular equipment while modifying the configuration of other tank walls connected to the modified tank wall as little as possible.

To this end, the invention provides a heat insulating edge block for the manufacture of a tank wall, said edge block comprising:

A generally rectangular bottom panel having a width direction intended to be oriented parallel to the edge of the tank wall and a length direction intended to be oriented perpendicular to the edge of the tank wall;

A substantially rectangular cover panel positioned above the bottom panel and parallel to the bottom panel;

Strut members positioned between the bottom panel and the cover panel and extending in a thickness direction of the edge block between the bottom panel and the cover panel to maintain the cover panel away from the bottom panel;

And an insulating lagging positioned between the bottom panel and the cover panel and between the support elements to fill the interior space within the edge block,

The cover panel having a recess open on a transverse edge of the cover panel at a location located between two longitudinal edges of the cover panel,

Wherein the support elements and the insulating insulated portion are positioned to form an open space below the concave portion of the cover panel,

The edge block includes a transverse metal anchoring strip affixed to a portion of the cover panel positioned between the recess and a first one of the two longitudinal edges of the cover panel, Wherein the anchoring strip extends parallel to the widthwise edge of the cover panel and the first end of the anchoring strip protrudes from a lateral surface of the edge block associated with the first longitudinal edge of the cover panel And a first tab,

The second end of the anchoring strip has a second tab projecting into the open space into and below the recess in the cover panel.

Depending on the construction method, such a heat insulating edge block may have one or more of the following characteristics.

According to one embodiment, the width dimension of the edge block between the recess and the first longitudinal edge of the cover panel is between the recess and the second one of the longitudinal edges of the cover panel Is greater than the width dimension of the edge block.

According to one embodiment, a portion of the cover panel, which is located between the concave portion of the cover panel and the second one of the longitudinal edges, has a concave portion, whereby the concave portion of the cover panel The perimeter and the perimeter of the bottom panel are set back from a generally rectangular circumference.

According to one embodiment, the recess extends along the thickness of the edge block so that the perimeter of the bottom panel in the recess is spaced away from the generally rectangular perimeter.

The recesses may have different shapes, particularly when it is desired to provide passage for the tank equipment, depending on the geometry of the tank equipment. According to one embodiment, the recess has the shape of a circular sector.

According to one embodiment, the support elements positioned between the bottom panel and the cover panel include side panels surrounding the bottom panel and around the periphery of the cover panel, surrounding the interior space of the edge block The side panels having a window provided above the recess in the cover panel to provide access to the open space located below the recess in the cover panel.

According to one embodiment, the support elements located between the bottom panel and the cover panel are arranged between the side panels parallel to the longitudinal direction of the bottom panel so as to define a plurality of compartments in the inner space of the edge block Further comprising mutually spaced load bearing struts located on the side of the heat insulating support, wherein the heat insulating retaining portion is inserted into the partition.

According to one embodiment, the open space located below the recess in the cover panel comprises one of the compartments delimited between the two load-bearing struts.

According to one embodiment, each tab of the anchoring strip includes a coupling portion that is bent toward the bottom panel.

According to one embodiment, each coupling portion includes a slot, the opening of which is longitudinally positioned opposite the widthwise edge of the cover panel from which the recess is opened.

 According to one embodiment, the adiabatic edge block intersects the widthwise anchoring strip and is attached to a portion of the cover panel located between the first longitudinal edge of the cover panel and the recess, .

According to one embodiment, the present invention also provides a closed adiabatic tank contained within a load support structure, said tank comprising a plurality of tank walls supported by load support walls of the load support structure, Wherein the wall includes a heat insulating barrier portion attached to each one load support wall of the load supporting structure and a sealing film supported by the heat insulating barrier portion,

Wherein the heat insulating block comprises a plurality of parallelepipedic insulating blocks each having a heat insulating reservoir and a cover panel facing the interior of the tank and wherein the upper surface of the cover panel opposite the heat insulating reservoir comprises a metal anchoring strip In addition,

Wherein the sealing film comprises a plurality of corrugated metal plates, each corrugated metal plate being welded to at least one anchoring strip of the insulating barrier,

The first load bearing wall supporting the first tank wall forms a second load bearing wall supporting the second tank wall and an arris of the tank,

Wherein the parallelepipedic insulating blocks of the insulating barrier of the first tank wall comprise rows of edge blocks arranged along corners of the tank, the edge blocks of the row of edge blocks having side surfaces facing each other, The column of edge blocks comprises a plurality of standard edge blocks,

Wherein an anchoring strip in the width direction for each of said standard edge blocks extends parallel to said edge of said tank over the entire width of said standard edge block, Each of the ends including a tab projecting from a respective side surface of the standard edge block into a space between the side surface of the standard edge block and a facing side surface of an adjacent edge block,

Wherein the column of edge blocks further comprises the above-described adiabatic edge block as a wider edge block disposed between the standard edge blocks, wherein the wider edge block is larger than the width dimension of the standard edge blocks Wherein an anchoring strip in the width direction of the wider edge block has the same length as an anchoring strip in the width direction of the standard edge blocks,

For each of the two tabs of the width direction anchoring strip supported by the standard edge block and the wider edge block, a first end anchored to the second load support wall and a second end anchored to the second end, Wherein an anchor rod comprising a second end coupled to said tab of said anchoring strip passes through a space between said side surfaces of said edge blocks and wherein said anchor rod comprises said standard edge blocks and said wider Is arranged to sever the tensile force between the anchoring strip and the second load bearing wall which is held by the large edge block.

Depending on the configuration, such tanks may include one or more of the following characteristics.

In one embodiment, all edge blocks in the first column are spaced apart, and an anchoring strip of each standard edge block extends parallel to the edge of the tank over the entire width of the standard edge block, Each of the two ends including a tab projecting from a respective side surface of the standard edge block into a space between the side surface and a facing side surface of an adjacent edge block,

Wherein the tank comprises a first set of anchor rods, each anchor rod including a first end anchored to the second load bearing wall, and for each of the two taps of the anchoring strip, Wherein the anchor rods are opposite the first end and have a second end coupled to the tabs, the first set of anchor rods having spaces between the respective side surfaces of the adjacent edge blocks, Extends into the open space of the large edge block and the anchor rods are arranged to transmit a tensile force between the anchoring strips and the second load bearing wall.

According to one embodiment, between the standard edge blocks, the second end of each anchor rod of the first set is jointly coupled to two separate taps, each of the taps extending from a side surface of each standard edge block Wherein the standard edge blocks are adjacent to one another and the anchor rod is arranged to transmit a tensile force between the anchor strips supported by the adjacent standard edge blocks and the second load support wall.

According to one embodiment, the parallelepipedic insulating blocks of the insulating barrier of the second tank wall comprise a second row of standard edge blocks arranged along the edge of the tank, and the standard edge block of standard edge blocks of the second column Have mutually spaced opposing side surfaces,

Wherein the width directional anchoring strips of each standard edge block of the second row extend parallel to the edge of the tank over the entire width of the standard edge block and each of the two ends of the anchoring strips comprises a non- A tab projecting from each side surface of the standard edge block into a space between the standard edge block and the adjacent standard edge block of the second row,

Wherein the tank includes a second set of anchor rods, each anchor rod including a first end anchored to the first load bearing wall, and wherein the side surfaces of adjacent standard edge blocks of the standard edge block of the second row In the space between them,

Wherein for each of the two taps of the anchoring strips, the second set of anchor rods is opposite the first end and has a second end coupled to the taps, the second set of anchor rods having a second end Support blocks of said first and second load-bearing walls and said anchoring strips of said edge blocks,

The spaces between the standard edge blocks of the first column are aligned with the spaces between the standard edge blocks of the second column.

According to one embodiment which is particularly suitable for the corner of 135 DEG, the first set of anchor rods are arranged in the space between the two load-bearing walls in the second row, and then in the space between the two load- The second set of anchor rods extending from the first load bearing wall in a space between the two edge blocks in the first row and in a space between the two edge blocks in the first row, And then extends in the space between the two edge blocks in the second column.

According to one embodiment, the width direction anchoring strip held by the edge block is attached to the cover panel of the edge block so as to have an attachment play in the longitudinal direction of the edge block.

The heat insulating blocks can be manufactured in different ways. According to one embodiment, each parallelepipedal insulating block includes, for example, a box made of plywood, in which a heat insulating underfloor is housed, the box comprising a bottom panel and a side wall extending between the bottom panel and the cover panel Panels. According to another embodiment, each parallelepipedic insulating block includes a bottom panel and a cover panel together with the foamed intermediate block.

According to one embodiment, the sealing membrane for each tank wall comprises:

A first set of corrugations projecting inwardly of the tank and extending along a first direction; And

And a second set of pleats projecting inwardly of the tank and extending in a second direction perpendicular to the first direction.

Different locations can be considered for the wrinkles of the sealing membrane. According to one embodiment, the first corrugation of the sealing membrane of the first tank wall is located opposite the space between the facing side surfaces of the edge blocks forming the corners of the tank. According to another embodiment, the first corrugation of the sealing membrane of the first tank wall is located on the opposite side of the edge blocks, for example on the cover panels of the heat insulating blocks.

According to another embodiment, for example, in patent FR 3008765, the membrane comprises metal strips.

According to one embodiment, the insulating barrier of the first tank wall or the second tank wall comprises parallelepipedic insulating blocks facing one longitudinal surface of the first or second row of edge blocks opposite the corner of the tank Wherein the upper surface of the cover panel of the cover panel of each of the elongated parallelepipedic insulating blocks comprises a recess opposite the recess in the upper surface of the cover panel of the corresponding edge block, The plate appears from the top surface of the cover panels to form a continuous flat support surface for the sealing membrane of the first tank wall or the second tank wall. Due to this characteristic, the distance between the rows of edge blocks and the extended blocks of the first row can be adjusted without creating any space in the support for the sealing membrane.

According to one embodiment, the standard edge blocks of the first column are smaller than the width of the elongated parallelepipedic insulating blocks of the insulating barrier of the tank wall in a direction parallel to the width direction of the edge blocks.

According to one embodiment, a thread is formed at a first end of each anchor rod, the first end is housed in a hollow cylindrical base member attached to the first load support wall and the second load support wall, The base member includes a wall having an opening through which the anchor rod passes, at one end opposite to the first load supporting wall or the second load supporting wall, wherein a nut having a dimension larger than the dimension of the opening is provided in the anchor rod 1 < / RTI > threaded end.

According to one embodiment, the anchor rod has a pivoting play so that the anchor rod can move in an anteroposterior direction with respect to the first load supporting wall or the second load supporting wall, .

According to one embodiment, each edge block in the first or second column, including standard edge blocks and possibly non-standard edge blocks, is a ledge protruding from the side surfaces of the heat insulating blocks, A plurality of attachment members attached to the first load support wall or the second load support wall, each of the plurality of attachment members including a pin extending perpendicularly to the first load support wall or the second load support wall, One end of the pin includes a plate supported against the upper surface of the ledge.

According to one embodiment, a bracket is attached to the ledge and the plate is supported on the upper surface of the bracket.

According to one embodiment, each tab includes a spaced portion extending from a corresponding side surface of a standard edge block parallel to the cover panel of the standard edge block, And a coupling portion extending from one end of the spacing portion toward the outside of the tank, wherein a second end of the corresponding anchor rod is coupled to the coupling portion of the tab.

According to one embodiment, each coupling portion includes a slot, wherein a first end of each anchor rod includes a hook, which is adapted to tightly couple the coupling portion of the tab and the hook, Respectively. With this feature, the anchor rods can be anchored to the taps of the anchoring strips in a stable and reliable manner, which assists in the construction of the tank walls.

According to one embodiment, the tank membrane comprises a row of metal angle pieces attached to the anchoring strips of the first row of edge blocks, each angle piece being attached to the anchoring strips of the first row of edge blocks, A first flat portion located in the plane of the sealing membrane of the one tank wall and a second flat portion attached to the anchoring strips of the second row of edge blocks and located in the plane of the sealing membrane of the second tank wall, Further comprising wrinkles extending in a direction intersecting the edge portion when the wrinkles of the corrugated metal plates of the sealing films extend.

According to one embodiment, spaces between adjacent edge blocks of the first and / or second loads and adjacent parallelepipedal insulating blocks and spaces between the edge blocks and the first load bearing walls are interposed between the insulated insulating walls .

According to one embodiment, the corrugated metal plates have a rectangular shape, each parallelepipedal insulating block comprising two intersecting anchoring strips, each anchoring strip having an anchoring strip for each side of each of the corrugated metal plates of the anchoring strips Extend in parallel.

Such tanks may, for example, form part of a landfill facility for storing liquefied gas or may be used in floating, coastal or deep-sea structures, in particular methane tankers, LPG transport tankers, floating storage and regasification unit, a floating production storage and offloading unit (HPSO), and so on.

According to one embodiment, the ship carrying the cold liquid material comprises a hull and the aforementioned tank located within the hull.

According to one embodiment, the present invention also provides a method for loading or withdrawing a cold liquid from such a vessel, wherein the cold fluid is passed through a heat-insulating pipe to a floating storage facility or a land storage facility To the tank of the ship, or from the tank of the ship through the insulated pipes to the floating storage or land storage facility.

According to one embodiment, the present invention also provides a low temperature liquid mass transfer system comprising: a vessel as described above; A heat insulating pipe arranged to connect a tank installed in the hull of the ship to a floating storage facility or a land storage facility; And means for controlling the flow of the low temperature fluid material from the floating storage or land storage facility through the insulated pipes to the tank of the vessel or from the tank of the vessel through the insulated pipes of the low temperature fluid material, And a pump to allow flow to the storage facility.

Certain aspects of the present invention are based on the concept that the heat insulating blocks forming the insulating barrier provide a closed, adiabatic tank that experiences little or no shear stress. Some aspects of the invention are based on the concept of providing a tank as described above wherein the anchor rod absorbs all of the tensile force from the membrane while the heat insulating blocks are primarily subjected to compressive stresses associated with the liquid contained in the tank. Some aspects of the invention are based on the concept of providing such a tank in a simple and economical manner. Certain aspects of the present invention are based on the concept of creating standardized boxes to form the insulating barrier in the corners of the tank described above. Some aspects of the invention are based on the concept of suppressing imbalance in the transfer of force between the sealing membrane and the load bearing structure. Some aspects of the invention are based on the concept of reducing imbalance in anchoring of the heat insulating blocks forming the insulating barrier of the tank wall.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention will be better understood in the course of the following description of some specific embodiments of the invention, given by way of example only and with no limitation, with reference to the accompanying drawings, And advantages will also become more apparent.
1 is a perspective view of a ship for transporting liquefied gas including a plurality of storage tanks.
Fig. 2 is a perspective view of a part of the tank of the vessel of Fig. 1 exemplifying the edge of the tank formed by the wall in the longitudinal direction of the tank and the wall in the width direction of the tank, wherein the wall in the width direction of the tank is It forms an angle of 90 ° with the wall.
Fig. 3 is a detailed exploded view illustrating the edge warming element of the insulating barrier of the tank wall of Fig. 2; Fig.
Fig. 4 is a detail view illustrating the two edge warming elements of Fig. 2, which together form a part of the edge of the insulating barrier for the tank of Fig.
Figure 5 is a detail view of an anchor rod associated with one end of an anchoring strip of the edge warming element of Figure 4;
Fig. 6 is a detailed view of the anchor rod of Fig. 4;
Figure 7 is a perspective view of a portion of the tank of Figure 1 illustrating the edge of a tank formed between two longitudinal walls of the tank at an angle of 135 [deg.] To each other.
Figure 8 is a detail view illustrating the two edge warming elements of Figure 7;
Figure 9 is a detail view of an anchor rod associated with the anchoring strip of the edge warming element of Figure 8;
10 is a top view of the tank wall at an edge portion illustrating the configuration of a modification of the edge warming elements.
Figure 11 is a schematic cut-away view of a tank of a methane or LPD transport tanker and of a terminal to which this tank is to be introduced / extracted.
Fig. 12 is a partial perspective view of the insulating barrier of the vessel of Fig. 1 in the vicinity of the corner between the longitudinal wall and the wall in the fittable and fitting direction;
Fig. 13 is a perspective view of the wall in the longitudinal direction of Fig. 12, in cross section along the diameter of the collecting wall.
14 and 15 are two perspective views of the edge insulating element of the insulating barrier of FIG. 12, adjacent to the collector.
Fig. 16 is a top view of the wall in the longitudinal direction of Fig. 12 showing the edge warming element and the windscreen. Fig.
Figures 17 and 18 are enlarged views of Zone XVII of Figure 12, each with no sealing membrane.
FIG. 19 is a top view of Zone XVII of FIG. 12, showing another embodiment of a sealing membrane around the collection.

The drawings are described below with reference to a load supporting structure comprising the inner walls of a ship's double hull for transporting liquefied gas. Such a load supporting structure has a polyhedral shape, for example, a prismatic shape. Figure 1 illustrates such a load supporting structure in which the longitudinal walls 1 of the load supporting structure extend parallel to the longitudinal direction of the ship and form a polygonal section in a plane perpendicular to the longitudinal direction of the ship. The longitudinal walls 1 meet each other at longitudinal arris 2, which form, for example, an angle of 135 degrees with the orthogonal geometry. The general structure of these polyhedral tanks is described, for example, in reference to FIG. 1 of document FR 3008765.

In the longitudinal direction of the ship, the longitudinal walls 1 are blocked by the load supporting walls 3 in the width direction, which is perpendicular to the longitudinal direction of the ship. The longitudinal walls 1 and the lateral walls 3 meet at the foreign object and at the rear of the corner portions 4.

Each of the walls 1, 3 of the load supporting structure supports the wall of each tank. Each of the tank walls includes at least one of a plurality of tank walls, including butane, propane, or propene, or other material, for supporting a sealing membrane in contact with a fluid stored in a tank, such as liquefied petroleum gas having an equilibrium temperature of -50 ° C to 0 ° C And an insulating barrier.

By convention, irrespective of the orientation of the tank wall associated with the earth's gravity, the adjective "top" applied to the tank element includes the portion of the element oriented toward the interior of the tank, and the adjective "bottom" ≪ / RTI > Similarly, the term "above " refers to a position located closer to the interior of the tank, and the term" below "refers to a position closer to the load support structure 1, irrespective of the orientation of the tank wall relative to the earth's gravity .

Fig. 2 is a view showing the relationship between one of the longitudinal walls 1 of the load supporting structure supporting the longitudinally extending tank wall 5 and the laterally wide tank wall 6 and one of the lateral walls 3 The corners of the tank at the longitudinal edge portions 4 of the tank are illustrated. The tank wall 5 in the longitudinal direction and the tank wall 6 in the width direction meet at the corner structure 7 of the tank and form an angle of 90 degrees in size. The tank wall 5 in the longitudinal direction and the tank wall 6 in the width direction have a similar structure, and only the longitudinal tank wall 5 is described below. The description of the tank wall 5 in the longitudinal direction is also applied to the tank wall 6 in the width direction.

The insulating barrier of the tank wall 5 in the longitudinal direction comprises a plurality of insulating elements anchored over all of the load bearing walls 1 in the longitudinal direction. These warming elements together form a flat surface with an anchoring of the sealing membrane of the tank wall 5 in the longitudinal direction. More specifically, these warming elements include a plurality of elongated warming elements 8 arranged together in a regular rectangular grid. Likewise, the insulating barrier of the longitudinal wall 5 comprises the rows of edge insulating elements 9, described with reference to Fig. 4, located along the edge 4. The warming elements 8, 9 are anchored to the load supporting structure by any suitable means, such as, for example, anchoring members 10 as described with reference to Fig. The warming elements 8, 9 are seated on the load bearing walls in the longitudinal direction through beads (not shown) of a middle sealing material forming parallel straight lines or parallel wave shaped lines. The intermediate space 11 separates the edge warming elements from the row of edge warming elements 9. The intermediate spaces 11 of the two tank walls 5 and 6 forming the corner portions of the tank are aligned with each other.

The sealing membranes for the tank wall 5 in the longitudinal direction comprise a plurality of metal plates 12 arranged together to overlap one another. These metal plates 12 preferably have a rectangular shape. The metal plates 12 are welded together to ensure that the sealing film is airtight.

The metal plates 12 can be deformed in response to various stresses exerted on the tank, in particular in the interior of the tank so that the sealing film can be deformed in response to thermal contractions, And a plurality of wrinkles 13 facing each other. More specifically, the sealing film of the tank wall 5 in the longitudinal direction comprises a first set of wrinkles 13 and a second set of wrinkles 13 forming a regular rectangular pattern. As illustrated in Figure 2, the first set of pleats 13 is parallel to the edge 4 and the second set of pleats 13 is perpendicular to the edge 4. Preferably, the corrugations 13 extend parallel to the edges of the rectangular metal plates. In the embodiment illustrated in FIG. 2, the corrugations 13 are located opposite the intermediate spaces 11. Thus, this embodiment does not require any plates to cover the intermediate spaces 11 to form a flat support for the metal plates. The distance between two successive wrinkles 13 in one set of wrinkles is, for example, 600 mm in size.

To ensure the continuity of the insulating barrier 2 in the corner structure 7, the metal corner plates 15 are welded and located on the vertical edge warming elements 9. These corner metal plates 15 include two flat portions 16 located within the faces of the sealing membrane of each tank wall 5 and 6, respectively.

3 is an exploded detailed perspective view of the edge warming element 9 of FIG.

The edge warming element 9 comprises a bottom panel 17, side panels 21, 22 and a cover panel 19. All these panels 17, 19, 21, 22 have a rectangular shape and define the internal space of the edge warming element 9. [ The bottom panel 17 and the cover panel 19 extend parallel to each other and are parallel to the load-bearing wall, as illustrated in Fig. The side panels 21, 22 extend perpendicularly to the bottom panel 17. The side panels 21, 22 connect the bottom panel 17 and the cover panel 19 over the entire perimeter of the edge warming element 9. The load-bearing struts 20 are located between the bottom panel 17 and the cover panel 19 in the interior space of the edge warming element 9. These load bearing struts 20 extend parallel to the longitudinal side panels 21. The lateral side panels 22 in the width direction extend perpendicularly to the longitudinal side panels 21 and include through openings 23. These through openings 23 allow the inert gas to circulate within the insulating barrier. The panels 17, 19, 21 and 22 and the load supporting struts 20 together form a box in which the heat insulating part 24 is located. The heat insulating portion 24 is preferably unstructured and made of, for example, perlite or glass wool.

The lower panel 17 includes longitudinally ledges 25 projecting from the longitudinal side panels 21. The bottom panel 17 also has a widthwise ledge 26 protruding from one of the lateral side panels 22 opposite the edge 4. Brackets 27 are supported by the ledges 25, 26 of the lower panel 17. [ In the example illustrated in Fig. 4, each end of the longitudinal protrusions 29 supports each bracket 27, and a central portion of the widthwise ledge 26 supports the bracket 27. [0033] Fig.

The cover panel (19) has a widthwise recess (28) on the upper surface opposite the heat insulating part (24). The recessed portion 28 in the width direction is located above the side panel 22 in the width direction and the widthwise ledge 26 of the lower panel 27 protrudes from the side panel 22 in the width direction. This widthwise recess 28 includes a recess 18 located opposite the bracket 27 which is supported by the widthwise ledge 26. A number of methods can be used to fabricate the cover panel 19. In the embodiment illustrated in FIG. 4, two laminate sheets having different dimensions are overlapped to form a cover panel 19 having a recess 28 in the width direction. In an unillustrated embodiment, the cover panel is composed of a sheet of plywood in which a rebate is formed to form a recess in the width direction.

4, the brackets 27 supported by the ledge 26 in the direction perpendicular to the longitudinal direction extend over the entire width of the edge warming element 9. In the embodiment shown in Fig. In addition, the cover panel 19 does not protrude above the widthwise ledge 26, so that the recess 18 may not be necessary.

The upper surface of the cover panel 19 also includes a widthwise rebate 29 and a lengthwise rebate 30. The rebate 29 in the width direction extends in the direction parallel to the width of the cover panel 19 over the entire width of the cover panel 19. [ The rebate 29 in the width direction is located close to the widthwise side of the cover panel 17 opposite the widthwise ledge 26. The rebate 30 in the longitudinal direction extends in a direction parallel to the length of the cover panel 19 over the entire length of the cover panel 19. [ Preferably, the rebate 30 in the longitudinal direction is located at the center of the width of the cover panel 19. In the embodiment illustrated in Figure 3, the rebate 30 in the longitudinal direction is located as an extension of the recess 18.

A longitudinal anchoring strip (31) is housed in a longitudinal rebate (30). This longitudinal anchoring strip 31 has a length that is shorter than the length of the cover panel 19. The thermal protection 54 (illustrated in FIG. 4) is located in the end portion of the longitudinal rebate 30 that is not occupied by the longitudinal anchoring strips 31.

Likewise, the anchoring strips 32 in the width direction are housed in the widthwise rebates 29 in the cover panel 19. [ However, this widthwise anchoring strip 32 extends over the entire width of the cover panel 19. Each end of the anchoring strip 32 in the width direction has a tab 33. These tabs 33 protrude from the respective longitudinal side surfaces of the cover panel 19.

In a manner similar to the edge warming elements 9, each extended warming element 8 has at its upper surface two vertical anchoring strips 14 housed in respective rebates. The anchoring strips 14 are located parallel to the edges of the metal plates 12, thereby preferably parallel to the corrugations 13. The anchoring strips 14 extend over the central portion of the rebates in which they are housed. Thermal protection 54 is located at the ends of the rebates.

The edge regions of the metal plates 12, 15 of the sealing membrane are welded to the anchoring strips 14, 31, 32 on which they are seated. The thermal protective sub-elements 54 prevent the thermal elements 8, 9 from being damaged when the metal plates 12, 15 are welded together to overlap each other. Welding of the metal plates 12,15 to the anchoring strips 14,31,32 makes it possible to fasten the sealing film to the insulating barrier but as a result of which the metal plates 12,15, The tensile force can be transmitted to the anchoring strips 14, (31, 32).

The tab 33 includes a spacer portion 34 which extends from the cover panel 19 as an extension of the rebate 29 in the width direction. This spacer also includes a coupling portion 35 that extends from one end of the spacer portion 34 opposite the cover panel 19. [ The coupling portion 35 extends in the direction of the lower panel 17. The coupling portion 35 includes a slot 52 that faces the widthwise side of the cover panel 19 where the widthwise recess 28 is located, that is to say, the side opposite the edge portion 4 It is open.

The anchoring strips 31, 32 are attached to the cover panel 19 by any suitable means, for example by means of rivets. The width directional anchoring strips 32 are attached, for example, to the presence of clearance in the longitudinal direction of the cover panel 19, which is one tenth of a millimeter in size. Typically, in the case of attachment by rivets, the rivets attaching the anchoring strips 32 in the width direction pass through the openings 36 in the cover panel 19. In addition to these bars, the openings 99 in the anchoring strips 31 and 32 that accommodate the rivets have a longitudinal dimension that is greater than the thickness of the rivet to allow clearance between the anchoring strips and the heads of the rivets. Likewise, the anchoring strips 32 in the width direction are spaciously housed in the rebate 29 in the width direction. This clearance is such that the tensile force generated in the longitudinal direction of the cover panel 19 by the sealing film welded to the anchoring strips 31 and 32 is not substantially transmitted to the cover panel 19, (43).

4 is a detail view illustrating an edge warming element 9 belonging to the longitudinal tank wall 5 and an edge warming element 9 belonging to the tank wall 6 in the width direction. The two edge insulating elements 9 together form an angle structure 7. The edges in the width direction of the edge warming elements 9 facing the edge portion 4 are arranged side by side. The edge warming element 9 belonging to the longitudinal tank wall 5 has a structure similar to the structure of the edge warming element 9 belonging to the tank wall 6 in the width direction. Only the edge warming element 9 belonging to the longitudinally extending tank wall 5 is described below.

Anchoring members 10 are illustrated in Fig. 4, and each anchoring member has a pin 38 welded to the load bearing wall 1 in the longitudinal direction. Each pin (38) extends perpendicular to the load bearing wall (1) in the longitudinal direction. A thread is formed at one end of the fins opposite to the load supporting wall 1 in the longitudinal direction. The square shaped bearing plate 39 includes a central opening (not shown) through which the pin 38 passes. A nut 40 is fitted to the threaded end of the pin 38. The bearing plates 39 of the respective pins 38 are engaged with the upper surfaces of the respective brackets 27 supported by the corresponding legs 25 and 26 of the lower panel 17 via the nuts 40 It will be maintained. In an unillustrated variation, the bearing plate is directly seated on the ledge (25 or 26) of the lower panel (17) of the edge warming element (9).

As illustrated in FIG. 2, these anchoring members 10 are also located at the corners of each of the running lagging elements 8. The side walls of each extended warming element 8 include projections. A bracket 27 is positioned on each of the ends of the projection. Each bracket 27 of the extended warming elements 8 cooperates with a respective anchoring member 10 wherein one support member 10 has a plurality of adjacent extended warming elements 8, Acting together with the brackets 27 of the extended warming elements 8. The corners of the adjacent extended warming elements 8 include recesses which together form a chimney opposite the corresponding mounting member 10. [ This chimney causes the nut 40 to be screwed onto the pin of the mounting member 10. [ These chimneys are filled with the insulating heat insulating portion 41 and covered with the cover plate 42 to form a flat surface with the cover panels of the heat insulating elements.

In the embodiment illustrated in FIG. 2, each extended warming element 8 has a width parallel to the edge 4, which is twice as large as the width of the edge warming elements 9. The extended warming elements 8 and the edge warming elements 9 are arranged such that the corners of two adjacent extended warming elements 8 are located on opposite sides of the widthwise ledge 26 of each of the edge warming elements 9 In the width of the edge warming element (9). The anchoring member 10 associated with the corners of the elongated warming elements 8 is thereby provided with a bracket 27 supported by the widthwise ledge 26 and a bracket 27 27). If appropriate, the recess 18 in the edge warming element 9 provides a space through which the tools necessary to tighten the nut of the anchoring element 10 pass.

In addition to these bars, the extended warming elements 8 located opposite the edge warming elements 9 are arranged in the recessed portion (not shown) in the edge warming element 9 opposite the recessed portion 28 in the edge warming element 9 28). Covering strips 53 are housed together in the recesses of the extended warming elements 8 and the edge warming elements 9 opposite each other to cover the space between the warming elements 8 and 9. This space is filled with a heat insulating part such as glass wool, for example. These covering strips appear on the upper surface of the cover panels of the warming elements 8 and 9 to provide a continuous flat surface for the sealing film. In addition, these cover strips 53 may occupy any construction clearance that may appear during the construction of the tank.

2, the sealing membranes of each of the tank walls 5 and 6 are arranged such that the tank walls 5 and 6 are in the region of the tank forming the corner structure 7, in order to prevent the sealing properties of the tank from deteriorating, The anchor rods 43 are anchored to the load supporting structure. More specifically, each edge warming element 9 has one side of the longitudinal side panels 21 connected to two anchor rods 43. More specifically, each anchoring tab 33 is coupled to each anchor rod 43. The combined action between the anchoring tabs 33 and the anchor rods 43 is similar for all anchor rods 43 in the tank. Only an anchor rod 43 anchored to an anchoring tab 33 illustrated in Fig. 4 is described below, and this description is similarly applied to all anchor rods 43 of the tank.

The anchor rod 43 is anchored to the load supporting wall 3 in the width direction. The anchor rod 43 extends perpendicularly to the load supporting wall 3 in the width direction from the load supporting wall 3 in the width direction. Thereby, the anchor rod 43 is anchored at its distal end to the load supporting wall 3 in the width direction, and is held in the intermediate space 11 between the two edge insulating members 9 of the tank wall 6 in the width direction And in the intermediate space 11 between the two edge insulating elements 9 of the tank wall 5 in the longitudinal direction.

One end 44 of the anchor rod 43 opposite the load supporting wall 3 in the width direction is connected to the tab 33 of the anchor strip 32 in the width direction. The stresses associated with the sealing film attached to the widthwise anchoring strip 32, for example, the stresses associated with entraining the liquefied gas into the tank, can thus reduce the forces transmitted to the load supporting wall 3 in the width direction , Thereby increasing the strength of the tank. These forces also pass through the sealing film, the anchor strips 32 in the width direction, and the anchor rods 43, without applying any major force to the cover panel 19. As a result, the edge warming element 19 experiences a negligible shear force.

Figure 5 illustrates how the anchor rod 43 works with the load-bearing wall and also the tab 33 of the anchor strip 32 in the width direction.

The anchor rod 43 is threaded at its end anchored to the load bearing wall. These threaded ends are housed in a hollow cylindrical base member. The hollow cylindrical base member includes a flat base 45 welded to the load supporting wall, a cylindrical wall 46 extending perpendicularly to the load supporting wall toward the inside of the tank, and a covering wall 47 parallel to the load supporting wall. . The covering wall 47 includes an opening through which the anchor rod 43 passes. The cylindrical wall 46 has an inner surface that is matched with a nut 48 housed within a hollow cylindrical base member. This matching of the shape between the nut 48 and the inner surface of the cylindrical wall 46 blocks the rotation of the nut 48 in the hollow cylindrical base member. In addition to these bars, the nut 48 has a dimension greater than the dimension of the opening through the covering wall 47, thereby locking the nut 48 within the hollow cylindrical base member. The threaded end of the anchor rod 43 is fastened into the nut 48 to ensure that the anchor rod 43 is anchored to the load bearing wall.

The end 44 of the anchor rod 43 supports a hook. As illustrated in FIG. 6, this hook has a U-shaped profile and anchor rod 43 penetrates its base 49. The arms 50 of the hook extend from the base 49 in the direction of the load bearing wall perpendicular to the base 49. The nut 51 is threaded onto the end 44 to secure the movement of the hook along the anchor rod 43. The first arm (50) of the hook engages the slot (52) in the anchoring tab (33). The coupling portion 35 of the tab 33 is interposed between the first arm 50 and the anchor rod 43 so that the base 49 is engaged with the slot 52 of the coupling portion 35 and the strap Lt; / RTI > In the embodiment illustrated in FIG. 5, a washer is disposed between the nut 51 and the base 49.

4, in the same manner as the manner in which the anchor rods 43 anchored to the load supporting wall 3 in the width direction are connected to the edge insulating member 9 belonging to the longitudinal tank wall 5, The anchor rod 43 anchored to the load supporting wall 1 in the longitudinal direction is connected to the tab 33 of the edge insulating element 9 belonging to the tank wall 6 in the width direction.

The first arm 50 of the hook of the anchor rod is connected to the first tab 33 protruding from the first edge insulator 9 into the intermediate space 11 and the second arm of the hook of the anchor rod 43 The anchor rod 43 is connected to the load supporting wall in each intermediate space 11 in the tank such that the anchor rod 43 is connected to the second tab 33 protruding from the second edge warming element 9 into the intermediate space 11. [ Lt; / RTI > The first edge warming element (9) and the second edge warming element (9) are adjacent to the intermediate space (11) and define the intermediate space (11).

In addition to these bars, the spaces 55 between the facing load bearing walls 1 and 3 and the edge insulating elements 9 are advantageously filled with a heat insulating part such as glass wool.

7 to 9 show the edge portions of the tank between two longitudinally extending tank walls 5 forming an angle of 135 DEG. These tank edge portions have a structure similar to the corner structure 7 of the tank forming an angle of 90 DEG, as described with reference to Figs. 2 to 6. The same reference numerals are used for elements having the same structure and / or function.

At the corner 2 forming an angle of 135 [deg.], The anchor rods 43 extend parallel to the membrane of the longitudinally extending tank wall 5 to which they are connected. 7 and 8, the anchor rods 43 form an angle of 135 DEG with the longitudinal load supporting wall 1 to which they are attached. In addition to these bars, an opening in the hollow cylindrical base member through which the anchor rod 43 penetrates is co-located with the covering wall 47 and the cylindrical wall 46 of the cylindrical base member.

 In this embodiment, the opening in the hollow cylindrical base member is defined by an angular play (not shown) of the anchor rod 43 relative to the hollow cylindrical base member about an axis parallel to the edge portion 2 of the load supporting structure ).

Figure 10 shows a schematic top view of the tank wall at a 90 ° edge according to an alternative embodiment. In the figures, the same elements or elements that achieve the same function have the same reference numerals increased by 100 for the reference numerals in Figs. 2-6.

In the variation illustrated in FIG. 10, the edge warming elements 109 have a width close to the width of the extended warming elements 108 and are aligned with the substantially extended warming elements 108. The width of the extended warming elements 108 is, for example, approximately 1200 mm, and the width of the edge warming elements 109 is approximately 1160 mm. In this variant, the corrugations (not shown) in the metal plates (not shown) are not on opposite sides of the intermediate spaces 111 but on the cover panels 119 of the edge warming elements 109. In addition, the metal plates (not shown) are welded discontinuously and only to the anchoring strips 132 in the central portion 156 of the anchoring strip 132 only. When such metal plates are discontinuously welded, the wrinkles act to extend so as to reduce deformation of the sealing film. The edge warming elements 109 are centered on the extended warming elements 108. Likewise, the anchoring strips 114 and 131 are positioned coaxially in the lengthwise direction perpendicular to the edges.

In this case, the edge warming elements 109 are anchored to the load supporting wall, such as the elongated warming elements 108, by the anchoring members 110 located at their corners. For the remainder, the structure of the tank wall is unchanged.

The tank wall of the modification illustrated in Fig. 10 can also be applied to the area of the angle of 135 [deg.].

Figs. 12 to 19 illustrate a lower load supporting wall 101 (Fig. 13) for supporting the tank wall 105 in the longitudinal direction and a load supporting tank wall 103 for supporting the tank wall 106 in the width direction. (Fig. 16) at different angles of the enclosed, adiabatic tank at the 90 DEG edges of the load support structure. The edge warming elements 109 and the extended warming elements 108 are constructed according to FIG. 10 over most of the walls. Accordingly, the same reference numerals in FIG. 10 are used to denote the same elements as those in this drawing. In addition to these bars, the edge warming elements 109 are hereinafter referred to as " standard "edge warming elements to distinguish the edge warming elements 109 from other edge warming elements that are specifically arranged around the pickle Lt; / RTI >

However, although most of the tanks are formed of the same structures that are repeated periodically, in particular standard edge warming elements 109 and extended warming elements 108, ) Are centered on the individual zones in the lower wall 101 in which they exist. 12) is formed in the insulating barrier portion of the tank wall 105 in the longitudinal direction around the collector 57 and a corresponding window 59 (Fig. 18) is formed in the sealing film .

Fig. 12 shows a perspective view of the insulating barrier of the two tank walls 105 and 106 around the augmentation, without showing the anchorage on the load supporting structure. 13 shows a perspective view of the tank wall 105 in the longitudinal direction taken in section along the diameter of the collector 57 parallel to the edge of the tank. Fig. 16 is a top view of the tank wall 105 in the longitudinal direction in the same region in Fig.

In this regard, the row of edge insulating elements on the bottom wall 101 includes a longer edge lagging element 209 located between the standard edge warming elements 109, and a shorter And a shorter edge lagging element 309, both of which are adjacent to the collecting cores 57. Gradually, the longer edge warming element 209 and the shorter edge warming element 309 occupy the same space as the two standard edge warming elements 109 along the edge, The entire modular configuration can be maintained. In particular, the row of edge insulator elements on the widthwise wall 103 only includes the standard edge insulator elements 109 in this region, since the periodic distribution of the anchor rods 143 is unchanged to be.

In describing the longer edge warming element 209, elements that are the same as or similar to those in Figures 2 to 6 have the reference numbers increased by 200 for the reference numbers in Figures 2 to 6, It will not be described in its entirety.

14 and 15 are two perspective views of a longer edge warming element 209 adjacent to the windshield 57, with and without a cover plate 219, respectively. As can be seen in these figures, the general shape of the longer edge warming element 209 has the shape of a rectangular parallelepiped having a width greater than that of the standard edge warming element 109, Was removed as a recess in the form of a circular arc that contributed to the intended circular recess 58 to accommodate the crystal structure. As a result, the arc-shaped concave portion 61 can be seen on the lower panel 217 and the cover panel 219. Just above the recesses 61, the side walls 62 form a plurality of flat planes that generally follow the arc forming the ledge on the bottom panel 217.

The bottom panel 217 is preferably monolithic to make the longer edge warming element 209 harder. The cover panel 219 also includes a lower panel 63 which is monolithic and which is precisely defined by a rectangular protrusion 225 and a widthwise protrusion 226 and a rectangular concave And covers the lower panel 217 except for the portion 64.

The recesses 64 extend over a portion of the longer edge warming element 209, for example, approximately one third, and extend in the longitudinal direction of the warming element, which is not affected by the recess 58 And is opened to the outside along the edge in the width direction facing the edge portion 204 at a distance from the edge portion. More specifically, the distance between the longitudinal edges and the recesses 64 is equal to the width of the standard edge warming element 109, whereby the width of the standard edge warming elements 109 in the widthwise direction of the anchoring strip 132 A widthwise anchoring strip 232 having the same dimensions may be disposed on the cover panel 219 between the indentations 64 and the distal edge in the longitudinal direction. In the concave portion 64, the coupling portion 235 of the anchoring strip 232 in the width direction penetrates into the open space 66 provided in the heat insulating insulating portion through the concave portion 64. More specifically, the open space 66 is formed from a compartment between the insulating support posts, e.g., the load support struts 220, which are wholly or partially absent of the glass wool.

A rectangular window 65 is provided in the lateral wall 222 in the width direction between the two load supporting struts 220 so that the opening space 66 from the wall in the width direction, ) (Figs. 16 and 17).

The cover panel 219 covers the lower panel 63 but does not cover the concave portion 228 in the width direction and does not cover the concave portion 64 in the longitudinal direction of the concave portions 68 And does not cover the wide square recess 69 intended to accommodate the connecting plate 60 (Fig. 17) around the collecting quartz 57, as shown in Fig. The upper layer of plywood 67 includes rebates 229 and 230 for anchoring strips 232 and 231.

Anchoring members for the longer edge warming element 209 on the lower wall 101 are illustrated in FIG. As can be seen, the collector 57 interferes with the positioning of the pins 238 on the load bearing wall, thereby locally deviating from the regular periodic distribution observed along the remainder of the load bearing wall (FIG. 10) , The period of this periodic distribution is equal to the width of the standard edge warming element 109.

Figure 16 also shows a shorter edge warming element 309 and its three anchoring members 310. In particular, along an edge in the width direction that faces the wall 103 in the width direction, the anchoring member 310 is positioned between the longer edge warming element 209 and the shorter edge warming element 309, Acts on both the warming element 209 and the shorter edge warming element 309 simultaneously. Along the longitudinal edges of the opposite sides of the collection fixture 57, the anchoring members 310 are rearranged along the above-described regular periodic distribution.

At the two ends of the anchor strip 232 in the width direction, the coupling portions 235 together act on an anchoring rod 243 configured as described previously. Only the anchor rod 143 shown in Figure 16 moves into the open space 66 and therefore does not act with the anchoring strip 232 because the collector 57 is positioned on the other side of the anchorage 143 Because it does not allow sufficient space to place the anchoring strip, the longer edge warming element 209 or the remainder of the shorter edge warming element 309.

Turning back to Figure 12, it can be seen that the circular recess 58 is formed by half in the longer edge warming element 209 and in the shorter edge warming element 309 and by half in the wider elongated adiabatic block 208 There will be. Along the circular recess 58, the lateral walls of the wider extended insulating block 208 can be configured in a manner similar to the lateral walls 62 of the longer edge warming element 209.

The shorter extended warming element 308 is positioned along the wider extended warming element 208 to occupy the same overall width as the two extended warming elements 108. [ This local deviation from the width of the extended warming elements 108 maintains a sufficient distance between the longitudinal side wall of the wider extended warming element 208 and the circular recess 58, . The anchoring member 210 illustrated in FIG. 16 is positioned to act with a longer edge warming element 209, a shorter, extended warming element 308, and a wider, extended warming element 208.

Figure 17 is an enlarged view of section XVII of Figure 12 showing the connecting plate 60 of the sealing membrane. Fig. 18 is a view similar to Fig. 17 in which a sealing film is shown.

The connecting plate 60 is formed over the square recess 69 of the longer edge warming element 209 and in the cover panels of the larger elongated warming element 208 and the shorter edge warming element 309 It is a square metal plate located over similar recesses. The connecting plate 60 is attached to these cover panels by bolts 8 or rivets distributed along its circumference.

The connecting plate 60 has a circular window 83 at the center thereof and the edge of this window is sealed airtightly against the annular plate 84 supporting the windshield 57 along the entire circumference of the windshield 57 do.

18, the sealing film is reinforced by an indented metal plate 212 around the collector 57, and the square window 59 is cut from the metal plate 212. As shown in Fig. Along the corners, the previously described angle metal plates 15 are also used in the windshield 57. In particular, the edges of the angle metal plates 15 and the edges of the square window 59 are welded in an airtight manner throughout the connection plate 60 around the windshield 57, and the sealing pieces 85 are used The wrinkles 13 of the membrane, which in the present example are two wrinkles parallel to the corners and two corrugations perpendicular to the corners, .

Figure 19 illustrates another embodiment of a sealing membrane around the collector 57 where the continuity of the wrinkles parallel to the edges is preserved. Elements that are the same as or similar to those of Fig. 18 have the same reference numerals.

In this case, two of the wrinkles 13 of the sealing film parallel to the corner must be blocked by the square window 59 due to their position and dimensions. Instead of blocking them in this way, these two wrinkles 86 and 87 can be formed by surrounding the square window 59 between the corner of the tank and the square window 59 in the case of the wrinkles 86, And locally deviated to move around the other side of the square window 59 in the case of the window 87.

To this end, this sealing membrane is formed by an assembly of smaller metal plates, in particular two trapezoidal plates 91 and 92, and two curved warped corrugated pieces 93 around the corrugation 57.

It should also be noted that two wrinkles 13 perpendicular to the corner are still blocked by the square window 59 and closed by the closure pieces 85 but two shorter wrinkles 94 Are provided in the trapezoidal plates 91 and 92 to provide local compensation for such blocking. In other words, the additional wrinkles 94 are locally deformed to provide the sealing film with the ability to compensate for relative losses elastically caused by cuts in the wrinkles. The additional wrinkles 94 are also closed by the closing pieces 85 at their two ends, respectively, on the angle metal plates 15 and the metal plate 12.

The tank wall structures illustrated in Figs. 12-19 may also be applied to a zone at an angle of 135 [deg.]. In this case, the anchor rods 43 illustrated in Figs. 7 to 9 are used in place of the anchor rods 143. Fig.

13, a hollow cylindrical container structure 90 is attached to the load supporting wall 101 around the opening 89 and protrudes outside the load supporting wall 101, Thereby forming an elongated structure rule that provides additional space for the < Desc / Clms Page number 7 > More specifically, the hollow cylindrical tubular structure 90 includes a cylindrical wall at the side which, for example, has a circular or other shape, the upper edge of which extends over the entire periphery of the opening 89 Is welded to a load bearing wall 101 and the structure 90 comprises a flat bottom wall 88 having a circular or other shape, for example a bottom wall, And is oriented perpendicularly to the load-supporting wall 101. The load- The hollow cylindrical container structure 90 may be made of a material similar to that of the load supporting wall 101. [ A detailed description of the structure of the amendment can be found in published document FR3023257.

Due to the wall structure described above, the tensions in the sealing membranes are also subject to local blockage in the widthwise anchoring strips supported by the heat of the edge warming elements, blockage caused by the presence of the corrugation 57 close to the corners of the tank Though, can be satisfactorily absorbed. In particular, the construction of the longer edge warming element 209 can make the widthwise anchoring strip 232 very close to the collector 57, such that the above-mentioned cut-off is relatively short.

Around the corrugation 57, the tensile force at the sealing membrane is absorbed by the connecting plate 60 which takes advantage of the stiffness of the longer edge warming element 209 to which it is partially attached.

Techniques for making tanks with the single sealing membranes described above can also be used for other types of tanks, for example, dual membrane tanks for liquefied natural gas (LNG) in coastal or floating facilities, such as methane An oil tanker or other oil tanker. In this context, the sealing membrane illustrated in the above figures may be considered as a secondary sealing membrane, and a primary insulating barrier and a primary sealing membrane (not shown) would still be added to this secondary sealing membrane . In this way, these techniques can also be applied to tanks having a plurality of overlapping, adiabatic and closed membranes.

Referring to Fig. 11, a cut-away view of a liquefied gas carrier vessel 70 shows a generally rectangular prismatic insulated tank 71 mounted in a double hull 7 of a ship. The tank wall 71 includes a primary hermetic barrier which is intended to come into contact with the liquefied gas contained in the tank and an insulating barrier provided between the hermetic barrier and the double hull 72. In the simplified version, the vessel has a single hull. In one embodiment, a secondary hermetic block is provided between the primary hermetic barrier and the ship's double hull 72, and a secondary thermal barrier is provided between the primary hermetic block and the secondary hermetic block.

In a manner known per se, the intake / extraction pipes 73 located on the upper deck of the vessel are connected to the sea 71 or to the marine or harbor terminal to transport liquefied gas from the tank 71 By means of suitable connection means.

Fig. 11 shows an example of a marine terminal including a loading / unloading station 75, an underwater pipe 76 and a land facility 77. Fig. The loading and unloading station 75 is a fixed coastal facility that includes a moving arm 74 and a tower 78 that supports the moving arm 74. The transfer arm 74 carries a bundle of separate flexible hoses 79 that can be connected to the intake / extraction pipe 73. The orientable movable arm 74 can be adjusted to any size of methane tanker. A connecting pipe, not shown, extends within the tower 78. The loading and unloading station 75 can be used to load or unload methane from a land-based facility 77 or into a methane tanker. Which includes a connected connecting pipe 81 connected to the inlet and outlet station 75 by a liquefied gas storage tank 80 and an underwater pipe 76. The underwater pipe 76 may allow liquefied gas to be conveyed between the entry and exit station 75 and the onshore facility 77 over a long distance, such as, for example, 5 km, whereby the methane tanker Lt; RTI ID = 0.0 > 70 < / RTI >

A pump provided on the ship 70 and / or a pump provided on the land-based facility 77 and / or a pump provided on the intake and extraction station 75 is used to generate the pressure required to transfer the liquefied gas.

While the present invention has been described in connection with certain specific embodiments, it is not intended that the invention be limited thereby in any way, and that all the technical equivalents of the means described with the combination thereof, It is obvious.

The use of the terms "comprises", "having", or "containing" and uses thereof does not exclude the presence of elements or steps different from those stated in the claims. A singular representation of an element or step does not exclude the presence of a plurality of such elements or steps, unless otherwise stated.

Nothing in the claims is to be construed as limiting the claim in any of the parentheses.

Claims (17)

As a heat insulating edge block (209) for producing a tank wall,
A generally rectangular bottom panel (217) having a width direction intended to be oriented parallel to the edge of the tank wall and a longitudinal direction intended to be oriented perpendicular to the edge of the tank wall;
A generally rectangular cover panel (219) positioned parallel to the bottom panel above the bottom panel;
Strut elements (220, 221) positioned between the bottom panel and the cover panel and extending in the thickness direction of the edge block between the bottom panel and the cover panel to position the cover panel away from the bottom panel , 222);
And an insulating lagging disposed between the lower panel and the cover panel and between the support elements to fill an interior space within the edge block,
The cover panel has a recess (64) positioned between two longitudinal edges of the cover panel and open on a widthwise edge of the cover panel, the support elements and the insulated, (66) below the concave portion of the cover panel,
A transverse metal anchoring strip 232 is attached to the portion of the cover panel positioned between the recess 64 and the first one of the longitudinal edges of the cover panel, The strip extends parallel to the widthwise edge of the cover panel,
Wherein the first end of the anchoring strip comprises a first tab (235) projecting from a side surface (221) of the edge block associated with a first longitudinal edge of the cover panel,
Wherein the second end of the anchoring strip comprises a second tab (235) protruding into the recess (64) and open space (66) of the cover panel. The method according to claim 1,
The width dimension of the edge block between the recess (64) and the first longitudinal edge of the cover panel is greater than the width dimension of the edge block between the recess and the second longitudinal edge of the longitudinal edges of the cover panel Width dimension of the insulating edge block. 3. The method according to claim 1 or 2,
The portion of the cover panel located between the recess and the second longitudinal edge of the longitudinal edges of the cover panel has a recess (61)
Wherein the recess extends along the thickness of the edge block so that the perimeter of the cover panel and the perimeter of the bottom panel are generally circumscribed by a generally rectangular circumference. The method of claim 3,
Wherein the recess has a shape of a sector of the circle. 5. The method according to any one of claims 1 to 4,
Supporting elements positioned between the bottom panel and the cover panel include side panels 221, 222, 62 surrounding the bottom panel and surrounding the interior space of the edge block, along the periphery of the cover panel ,
The side panels having a window (65) provided above the recess (64) in the cover panel to provide access to an open space located below the recess in the cover panel. 6. The method of claim 5,
The support elements located between the bottom panel and the cover panel are spaced apart from each other by mutually spaced apart strut struts located between the side panels parallel to the longitudinal direction of the bottom panel to define a plurality of compartments within the interior space of the edge block ) ≪ / RTI > 220,
The open space 66 located below the recess in the cover panel includes one of the compartments delimited between the two load-bearing struts 220. The heat- . 7. The method according to any one of claims 1 to 6,
Wherein the anchoring strips (232) of the edge blocks (209) are attached to the cover panel (219) of the edge block with a play in the longitudinal direction. 8. The method according to any one of claims 1 to 7,
Wherein each tab of the anchoring strip (232) comprises a coupling portion (235) curved toward the bottom panel. 9. The method of claim 8,
Each coupling portion 235 includes a slot 52 in which the opening is oriented in a longitudinal direction opposite the widthwise edge of the cover panel from which the recess 64 is open. 10. The method according to any one of claims 1 to 9,
Further comprising a longitudinal anchoring strip (231) attached to a portion of the cover panel intersecting the width direction anchoring strip and positioned between the first longitudinal edge of the cover panel and the recess, . A sealed, adiabatic tank constituting a load supporting structure,
Wherein the tank includes a plurality of tank walls (5,6) supported by load support walls (1, 3, 103) of the load support structure, each tank wall (5,6) And a sealing film supported by the heat insulating interrupting portion, wherein the heat insulating interrupting portion is attached to each of the load supporting walls (1, 3, 103)
The heat insulating block includes a plurality of parallelepipedic insulating blocks 8, 9, 108 and 109, and each of the heat insulating blocks 8, 9, 108 and 109 has a heat insulating retaining portion 24 and an inside of the tank And the upper surface of the cover panel (19, 119) opposite the heat insulating part (24) supports the metal anchoring strips (14, 31, 32, 114, 131, 132) In addition,
Wherein the sealing film comprises a plurality of corrugated metal plates 12 and each corrugated metal plate 12 is welded to at least one anchoring strip 14, 31, 32, 114, 131, 132 of the insulating barrier. And,
The first load bearing wall 1 supporting the first tank wall is provided with the edge portions 2, 4 and 104 of the tank together with the second load bearing walls 1, 3 and 103 supporting the second tank wall Lt; / RTI &
The parallelepipedic insulating blocks 8, 9, 108 and 109 of the insulating barrier of the first tank wall 1 are provided with edge blocks 9 and 109 arranged along the corners 2, 4 and 104 of the tank , Wherein the edge blocks (9, 109) of the row of edge blocks (9, 109) have side surfaces facing each other,
The row of edge blocks includes a plurality of standard edge blocks 9 and 109 and the widthwise anchoring strips 32 and 132 of each of the standard edge blocks 9 and 109 are connected to the standard edge block 9 Of the width directional anchoring strips 32 and 132 supported by the standard edge blocks 9 and 109 and extending parallel to the edges 4 and 104 of the tank over the entire width of the tank Each of the ends is spaced from a respective side surface of the standard edge block 9,109 to a side surface of the standard edge block 9,109 and a facing side surface of the adjacent edge block 9,109 11, < RTI ID = 0.0 > 111, < / RTI &
The column of edge blocks further comprises a larger edge block (209) according to any one of claims 1 to 10 arranged between said standard edge blocks (9, 109), said width The larger edge block has a dimension in the width direction greater than the width dimension of the standard edge blocks 9 and 109 and the width direction anchoring strip 232 of the larger width edge block has a dimension 132 have the same length as the widthwise anchoring strips 32, 132,
For each of the two tabs 33 of the width direction anchoring strips 32, 132, 232 supported by the standard edge block and the larger width edge, the second load support walls 1, 3, 103 And an anchor rod (43, 143) including a first end anchored to said tab (33) and a second end (44) joined to said tab (33) of said anchoring strip (32, 132) 111 and between the side surfaces of the edge blocks 9, 109, 209 and the anchor rods 43, 143 are connected to the standard edge blocks 9, Is arranged to transmit a tensile force between said anchor strip (32, 132, 232) and said second load bearing walls (1, 3, 103) supported by a larger edge block (209). 12. The method of claim 11,
The anchor strips 32 and 132 of each standard edge block 9 and 109 are spaced apart from one another by the total width of the standard edge blocks 9 and 109, Wherein each of the two ends of the anchoring strips (32, 132) extends from a respective side surface of the standard edge block (9, 109) (33) projecting into a space (11, 111) between the side surfaces and the facing side surfaces of the adjacent edge blocks (9, 109)
The tank includes a first set of anchor rods (43, 143), each of the first set of anchor rods (43, 143) including a first end anchored to a second load bearing wall, For each of the two tabs 33 of the strips 32, 132 and 232, each of the anchor rods 43, 143 and 243 of the first set is located opposite the first end, And the first set of anchor rods 43,133 and 243 have a second end 44 which is spaced apart from the space between the respective side surfaces of the adjacent edge blocks 9,109, 111 and the open width of the larger edge block 209 and the anchor rods 43, 143 and 243 are connected to the anchoring strips 32, 132, 232 and the second load- (1, 3). ≪ / RTI > 13. The method of claim 12,
Between the standard edge blocks, the second end 44 of each anchor rod 43, 143 of the first set is communally coupled to two separate taps 33, each tab 33 The standard edge blocks 9 and 109 are adjacent to each other and the anchor rods 43 and 143 extend from the side surfaces of the standard edge blocks 9 and 109 of the adjacent standard edge blocks 9 and 109, 103, 103) and the anchoring strips (32, 132) supported by the second load bearing walls (1, 109). The method according to claim 12 or 13,
The parallelepipedic insulating blocks 8, 9, 108, 109 of the insulating barrier of the second tank wall 6 are connected to standard edge blocks 9, 9, 108, 109 arranged along the corners 2, 4, 109, the standard edge blocks 9, 109 of the second row having mutually spaced opposing side surfaces,
The width direction anchoring strips 32 and 132 of each of the standard edge blocks 9 and 109 of the second row extend along the entire width of the standard edge blocks 9 and 109 to the corner portions 2, , Each of the two ends of the anchoring strips (32, 132) extending from the respective side surface of the standard edge block (9, 109) of the second column to the standard edge block (9, 109 And a tab 33 protruding into spaces 11 and 111 between adjacent standard edge blocks 9 and 109,
The tank includes a second set of anchor rods 43 and 143 and a second set of anchor rods 43 and 143 each include a first end anchored to the first load bearing wall 1 And passing through spaces 11 and 111 between the side surfaces of adjacent standard edge blocks 9 and 109 of the standard edge blocks 9 and 109 of the second row,
Wherein for each of the two taps (33) of the anchoring strips (32, 132) the second set of anchor rods (43, 143) are located opposite the first end, (44) and the second set of anchor rods (43, 143) has an anchoring strip (32, 132) of the standard edge blocks (9, 109) (1), wherein the tensioning means
The spaces 11 and 111 between the standard edge blocks 9 and 109 of the first column are aligned with the spaces 11 and 111 between the standard edge blocks 9 and 109 of the second column, Insulated tank. As a vessel 70 carrying a low temperature liquid material,
A ship comprising a hull (72) and a tank according to any one of claims 11 to 14 located within the hull. A method for loading or extracting a low-temperature liquid into a ship (70) according to claim 15,
The low temperature fluid is transferred from the floating storage or land storage facility 77 to the tank of the ship 71 via the heat insulating pipes 73, 79, 76 and 81, To a floating storage facility or a land storage facility. A low temperature liquid mass transfer system,
The ship (70) according to claim 15,
(73, 79, 76, 81) arranged to connect a tank (71) provided in the hull of the ship (70) to a floating storage facility or a land storage facility (77)
The low temperature fluid material is allowed to flow from the floating storage or land storage facility 77 to the tank of the ship 71 via the adiabatic pipe or from the tank of the ship 71 to the floating storage facility or land storage facility 77). ≪ / RTI >

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