NO115057B - - Google Patents

Abstract

1,003,615. Storing liquefied gases. GAZ DE FRANCE. June 20, 1963 [June 12, 1962], No. 24589/63. Heading F4P. A tank for storing and transporting liquefied gas comprises an inner casing 20 disposed within and spaced from an outer compartment 10 by the interposition of solid insulating blocks 30 adapted to transmit to the walls of the outer compartment the pressure exerted on the inner casing 20 while co-operating in guiding the inner casing during its expansion and contraction movements, and the remaining space between the inner casing and outer compartment being filled with granulated or powdered insulating material. The inner casing 20 is guided by T-sectioned elements 70, Fig. 8, secured to the outer faces of the inner casing and co-operating with T-sectioned grooves 71 formed in the blocks. Each of the faces of the inner casing are provided with four T-sectioned elements 70 arranged at 90 degrees to each other as shown in Fig. 2. In an alternative arrangement the inner casing is guided by pairs of chains 81, 82, Fig. 9, one of the ends of each chain being secured to the outer 'compartment at 84 and 85 and the other ends to a common point 83 on the inner casing. The insulating blocks 30 may be of cubic, prismatic or lozengesectioned, preferably arranged in staggered rows in order to avoid the ramming of the insulating powder. The insulating blocks 30 are secured to the walls of the outer compartment by glueing or by means of angle members secured to the compartment (Figs. 3 and 4 not shown), or alternatively may be secured at regular intervals on steel ropes (Fig. 7, not shown), the faces of the blocks which contact the inner casing being coated with a layer of a material having a low coefficient of friction such as hardwood to facilitate sliding therebetween. In another embodiment (Fig. 14, not shown), the insulating blocks are disposed in vertical row and the inner casing has alternate flat and curved portions. The inner casing may be strengthened by stiffeners 110-114 arranged as shown in Fig. 15 (or Fig. 17, not shown), welded or strapped to the outer or inner faces of the casing. Alternatively stiffeners may be nailed or glued to boards of impregnated wood disposed on the outer face of the inner casing, or to the insulating blocks. A further embodiment (Figs. 19 and 20, not shown), describes an arrangement wherein the solid insulating blocks are replaced by a grid or network of hardwood beams built up of parallel rows of beams crossed by parallel rows of beams in other planes.

Description

rods or similar placed in the interior of the inner jacket and which allow a better

division of powers.

A limited number of intermediate layers usually an-

arranged between the inner casing and the outer casing and forms support for the inner container and ensures its stability. However, the rigidity of the inner container must be high.

Finally, a technique is also known according to which the deviant contractions and expansions between the inner mantle and outer man-

the wire is taken up by elastic deformation of intermediate elements arranged between the inner and the outer mantle.

None of these constructions allow the realization of a light container with a thin inner jacket that does not have expansion joints or a device that allows the absorption of the

known deformations between the inner and the outer mantle in the container, as the implementation of all these devices leads to very com-

plex and expensive designs.

According to the invention, a container is used

for storage and transport of liquefied gas at very high temperatures, such as liquefied met-

he, which container comprises an inner mantle of substantially parallelepipedal shape with cylindrical corner edges and a rounded top housed in a rigid, substantially parallelepiped-

disk space, as the inner mantle is intended for

to contain the liquefied gas and its dimensions are only slightly smaller than the dimensions of the room, and the container according to the invention is distinguished by the fact that the walls of the inner mantle are thin, flexible and smooth and are supported in a manner known per se by intermediate elements of solid insulating material that is un-

movably attached to the inner walls of the rigid room, as the intermediate elements offer each of the aforementioned mantle's flat walls a connection, so to speak

gending planar support surface, so that said mantle's expansions and contractions induce displacement of its planar walls on their respective support surfaces and are absorbed by variation of the arc of the corner edges and the arc of the rounded tops, which for this purpose have a large radius.

Quite simply, it can be said that under the influence of temperature variations, the container expands

their inner mantle expands and contracts,

as it rises or sinks in the interior of the outer mantle by sliding along the multiple fixed intermediate elements that control it and over-

leads the compressive forces to the outer rigid space. These effects of the expansion of the inner jacket of the container can be allowed by the special shape of the jacket comprising corner edges with cylindrical

risk shape and tops with a rounded shape with a large radius of curvature and the continuous parallelepiped shape of the outer rigid space, in which the inner tight mantle can thus move.

In contrast to the known technique possible-

is thereby made arrangement of extremely small thick

looks for the inner casing because the pressure forces absorbed by this casing are at all times carried by intermediate guide elements which are

get close together and offer a plan and mainly

continuous support surface which in turn is supported by the outer rigid space.

On the other hand, with this method of construction it is absolutely unnecessary to arrange expansion joints or complicated specific shapes of the inner casing surface in order to

slow recording of the extensions.

Compared to the known designs with

the invention brings the following advantages:

— The continuous inner mantle, e.g. consisting of welded together metallic pla-

ter, as the expansions and contractions

is taken by deforming the corner edges and the rounded tops of an inner mantle of mainly parallelepipedal shape. — A very small thickness is necessary for the inner casing because this rests on guide elements that lie close to each other and are immovably attached to the outer casing, which means that there are never any significant shear forces or tensile stresses that must be tolerated.

— This extremely simple, fast and low-cost

only the construction method of such a container means that it is not necessary for such a construction to satisfy exact tolerances or special and fine expansion joints.

The invention thus allows the production of

a container for storing and transporting liquid

made gas at very low temperatures, which has an inner jacket with reduced weight, by as far as possible using a powdered thermal insulation

ring which has no bracing system and which it is possible to place in a ship or other vessel by making maximum use of the dispo-

nible rooms.

According to another feature of the invention if-

the aforementioned inner casing on its side walls up and down angle irons, profiles or the like arranged in a cross, preferably mainly along the center lines or diagonals of the walls, as the angle pieces can slide on or in a guide path

arranged in any of the aforementioned intermediate ele-

ments, so that the crossing points of said center lines or diagonals form fixed points during the expansion and contraction of the corresponding walls.

These and other features will appear from the following

gent description.

The attached exemplary drawings show

fig. 1 a vertical section of the container according to the invention, fig. 2 shows the container according to fig. 1 in horizontal section along the line 2—2 in fig. 1, fig. 3

shows in vertical section the insulating distance elements

ments which are designed as essentially parallelepipedic cubes and which, according to one embodiment, are used to form thermal insulation

tion of the one in fig. 1 and 2 shown container, before the finely divided insulation material is put in place,

fig. 4 is a vertical section through the inner casing and the wall of a container space according to fig. 3 and shows how the distance elements are attached to the walls of the room, fig. 5 and 6 are equal

nende vertical section as fig. 3 and shows other types of insulation elements according to other embodiments, after the finely divided insulation material has been placed, fig. 7 shows another suspension of insulation elements in the space between

lom the inner mantle and the wall of the room,

fig. 8 shows in vertical section along the line 8-8 in fig. 1 the control of the inner mantle in the container on cubes resting on the diamond base, fig. 9 shows, seen from below in partial section, the control of the inner casing according to an embodiment which uses chains, and fig. 10 is a vertical section of bottoms in the inner mantle and in the space along the line 10—10 in fig. 9; fig. 11 is a section through a vertical insulating partition in the container and shows a chain which connects the inner jacket with the room wall and which serves to resist the pressure of the insulating powder, fig. 12 is a geometrical drawing which schematically shows the deformations of the rounded edges in the container during the temperature variations, fig. 13 is a partial vertical section of a container and shows the supports used according to one embodiment, fig. 14 is a horizontal section through the vertical insulating walls in a container according to an embodiment, fig. 15 schematically shows the arrangement of metallic stiffening members which are welded to the outer jacket in the container, and which cooperate with a set of insulating cubes to improve the resistance of the jacket, the jacket not being shown in the drawing for the sake of clarity, fig. 16 is a section on a larger scale along the line 16-16 in fig. 15, and shows the arrangement of an insulating cube which is supported on the wall in the room where the container is placed, and in the figs. 15 shown bracing elements, fig. 17 shows the arrangement of reinforcements of poorly conductive material resting on the insulating cubes, the container's mantle and the floor between the mantle and the reinforcement-forming elements not being shown for the sake of clarity, fig. 18 is a section along the line 18—18 in fig. 17 on a larger scale with a partial section, and fig. 19 and 20 show in plan view and in section on a larger scale the coordination of spacer elements consisting of a number of beams of poorly conductive material arranged in parallel planes to the surfaces of the mantle according to an embodiment of the invention.

As mentioned above, the container according to the invention comprises an outer shell (e.g. a ship's cargo hold) which is substantially parallelepiped and where, under an interlayer of such a mixed insulating material (solid and powdered material), a similarly parallelepiped inner shell is arranged, but with -rounded corner edges and top. Control devices (insulating cubes and suspension elements, such as struts and chains) are arranged so that the planar surfaces in the mantle can remain substantially in their planes during the container's temperature variations. Fixed points on all surfaces or on part of them are provided either by means of angle pieces or by means of inclined chains, the expansions and contractions of the inner mantle occurring from these fixed points simultaneously with the deformations which practically only act on the rounded parts (edges or corners) in the inner casing.

In the following, various elements of which the container consists are described in accordance with different embodiments of the invention.

As shown in fig. 1 and 2, the container according to the invention essentially consists of an inner jacket 20 of "elastic" metal, i.e. of metal which can withstand very well the very low temperatures in the liquid to be stored and transported, and of an outer jacket 10 formed by a wall in a ship's room or other vessel. The outer casing 10 can either be a rigid casing placed on the frameworks of a ship, or it can be completely or partially formed by side walls or the transverse partitions which form part of the ship's hull.

As shown in fig. 1 and 2, the space 10 is essentially parallelepiped and comprises side walls 12, 13, 14, 15 which are mainly vertical, and a roof 16 and a bottom 17 which are mainly horizontal. The inner casing 20 is also substantially parallelepiped, its vertical walls 22, 23, 24, 25 are planar and substantially parallel to the walls 12, 13, 14, 15 of the room and its roof 26 and bottom 27 are parallel to the roof 16 and bottom 17 in the room. The corner edges of the mantle 10 are rounded and designed mainly as quartz cylinders with a large radius of curvature, so that the corners in the inner mantle have a substantially spherical or conical shape, the radius of curvature of these corners being the same as in the rounded edges.

The space between the inner casing 20 and the walls of the room 10 is filled with thermal insulation. As shown in fig. 1 and 2, there are regularly arranged elements or cubes of a compact insulating material, such as cork, balsa wood, expanded insulating material, etc., whose height is equal to the distance between the walls in the inner mantle and in the space directly above each other (ie walls 22 and 12, 23 and 13, 24 and 14, 25 and 15, as far as the vertical walls are concerned, and walls 26, 16 and 27, 17, as regards the roof and bottom of the container). Then, using a method known per se, a finely divided insulation material that is powdered or granulated is placed in place between the cubes. It ei1 in fig. 1 and 2 denote by 30 the cubes which are placed in the space between the inner mantle 20 and the walls of the room 10.

The dice are attached to the outer shell either by gluing or by other suitable means, but their contact surface with the inner shell can freely slide against this surface. The compact insulating material used for the cubes according to the invention has a sufficient resistance to compression to be able to transmit the outwardly directed pressures of the fluid enclosed in the inner casing, namely the pressure (hydrostatic pressure) of the liquid in the container, or of the gas that is located above the liquid. It will be understood that account should be taken of the hydrostatic pressure in the liquid by arranging a greater number of cubes of solid insulating material at the bottom of the container than at the top of the container. Such a device allows stiffening elements which are usually arranged in containers of this type to be looped to reinforce the mantle.

The dimensions of the cubes are preferably relatively small, because it is known that at the very low temperature in the inner mantle, solid insulation materials are easily exposed to crack formation, and that with such types of construction, elements with large dimensions should be avoided.

The compact insulation material makes up 1/10 to 1/4 of the total volume of the thermal insulation.

Fig. 3 and 4 show zigzag arranged cubes with a mainly square cross-section, arranged along the vertical wall of the container according to the invention. 31 denotes the vertical wall in the room on which the dice 32 are attached. To attach the dice, L-shaped angle pieces 33 are used on the one hand and plates 34 on the other, the attachment elements 33 and 34 being arranged in such a way that the diagonals of cubes with a square cross-section 32 are vertical and horizontal. Such a device allows the powder that makes up the finely divided insulating material to easily flow out in accordance with its controlled angle and that empty pockets of finely divided insulating material are not formed under the cube-forming elements 32 when the insulating powder is refilled. Fixing elements 33 and 34 are also arranged on the wall 31, so that the insulating elements are arranged in a zigzag pattern. By means of such a device, clumping of the powder is avoided and a downward movement of the powder is prevented.

The surface of the cubes, which is in contact with the outer wall of the inner casing, is coated with a layer of a material 36 which has a low coefficient of friction (e.g. a layer of plywood), so that the sliding of the inner casing against the cubes is relieved.

Fig. 5 and 6 show two other embodiments for the insulation of the vertical partitions. Fig. 5 shows elements in the form of asymmetric rhombuses whose lower tip forms a smaller angle than the upper tip. The angle a which the lower surface 41 of insulating cubes 40 forms with the horizontal line is large, which allows the application of a powdered insulating material with a sharp angle of attack. Those in fig. 6 shown elements 50 which form the insulating cubes are substantially parallelepipedic and they are provided with a pointed base surface, and the angle of the lower surfaces of the elements 50 which are denoted by b is substantially smaller than the angle a shown in fig. 5. The one in fig. The device shown in 6 is advantageously used for a very finely powdered insulating material which has a less sharp angle of attack than the angle b in relation to the horizontal line. It is in fig. 5 and 6 do not show how the cube-shaped insulating elements 40 and 50 are attached to the wall in the space in which they form an insulation together with the insulating powder. It will be understood that one can advantageously use a device similar to the device shown in fig. 3 and 4 for the elements 32.

In fig. 7 shows another method of attachment of insulating elements which are designed essentially as cubic cubes 60 arranged between the vertical wall of the space 61 and the inner mantle 62. According to this embodiment, there passes through the elements 60, along a vertical line connecting their upper edge 63 and lower edge 64, a steel cable 65 passing through them from one end to the other end, V-shaped plates 66 which are firmly connected to the cable 65 and which are attached to the cable at a suitable distance prevent the sliding of the -ning-shaped elements 60 along the cable 65. The cable 65 is suspended in any way on the tip of the container. It will be understood that such a device allows a rapid disassembly of the elements 60 after the powder in which the elements 60 are immersed has been removed, e.g. when pumping. Such rapid disassembly allows time to be saved during the frequent inspections to which transport containers for the very cold liquid are regularly subjected.

As mentioned above, at least one central point on each surface of the inner mantle is firmly connected to the immediately above wall in the room, so that the mantle is forced to deform under the temperature variations from this point on as the plane walls of the inner mantle are kept parallel to the room -the walls, so that practically only the rounded parts are deformed. In order to achieve the above-mentioned fixed points, there is in that in fig. 1, 2 and 8 shown example between the walls of the inner mantle 20 and in the space 10, arranged sliding paths which in the shown example are arranged according to the center line of the corresponding surfaces in the parallelepiped container (it will be understood that these sliding paths can be arranged according to diagonals or other lines converging towards the center of the surface in question).

Fig. 8 shows in section the device arranged between the bottom 27 of the inner casing 20 and the bottom 17 in the room 10. Profile parts, e.g. T-shaped, are attached to the outer surface of the base 27 in the inner casing 20. These profile parts, denoted by 70, engage in a T-shaped groove 71 arranged in the upper part of the cubes firmly connected to the base 17 in the room 72. The cubes 72 are made of hard wood which is a poor heat conductor, such as oak wood. The cubes 72 may also consist of two parts, namely a part in which the groove 71 is placed, of hard wood, and another part of less hard but better insulating wood, such as balsa wood or the like, or of expanded insulating material, as the elements which form the cubes 72 are firmly connected to each other and also fixed

connected to the bottom wall 17 in the space 10. It will be understood that the control obtained by means of angle pieces 70 in the cube-shaped element rows 72 will provide for the lower wall of the container a fixed point which represents the point at which the center lines of the bottom wall 27 meet each other, and as in fig. 2 is denoted -by 75.

The control of midpoints in the walls of the inner casing 20 in relation to the corresponding walls in the room 10 can be provided in the same way as the control of the lower wall 27 in the internal casing in relation to the wall 17 in the room, as schematically shown in fig. 1 and 2.

Figs. 9 and 10 show another embodiment for the control of the walls in the inner mantle, and this embodiment can be used by itself for one, several or all walls, or in combination with the device described above (the angle piece that slides in a tracks of suitable shape). In fig. 9 and 10, 30 designates the cubic cubes that make up the fixed insulating elements placed, e.g. between the lower wall 27 of the inner jacket 20 in the container and the lower wall 17 of the room 10. It has been assumed that the insulating powder has not yet been placed in it in fig. 9 and 10 showed an example to make the drawing clearer, but it is clear that the device described in the following should be immersed in the same way as the cubes 30, in a layer of powdered insulating material placed between the walls 17 and 27. In order to achieve the control along a center line as in fig. 9 is shown with a dash-dot-drawn line m—m (which control in the example shown in Fig. 8 is achieved by the interaction of the angle piece 70 with the groove 71), chain pairs 81 have been attached at several points of the line m—m, 82 which diverge from their attachment points on the line m— m, towards the inner casing 27 of the container. The ends of chains 81 and 82, denoted respectively by 84 and 85, are attached to hooks or claws arranged on the wall 17 of the room. It will be understood that such a device only allows a movement of the inner casing 27 in relation to the wall 17 along the center line m-m. By arranging two rows of chains along the two center lines which meet each other (as shown in Fig. 2) at 75, a fixed point is obtained at point 75 during the expansions and contractions of the inner casing 10. An identical arrangement can also be used at the top of the container to connect the upper wall 26 of the inner casing 20 with the upper wall 16 of the room 10, as well as at other walls. The device described above has the meaning that the chains 81 and 82, which practically have a constant length, continuously press the corresponding wall of the inner jacket 20 against the surfaces of cubes 30 which make up the solid part of the insulation, so that the insulating powder cannot penetrate between the cubes 30 and the outer walls of the inner casing 20.

Fig. 11 shows the two vertical partitions 24 in the inner casing and 14 in the container, connected to each other by means of a chain 90. Chains, such as the chain 90, or other elements that form poorly heat-conducting stays, are arranged between the respective vertical and horizontal walls in the inner mantle 20 and in the room 10 which lie directly opposite each other. This device allows free movement of the inner jacket in the container and keeps the distance between the vertical and horizontal walls completely constant, these distances practically corresponding to the height of the fixed insulation cubes. The connecting chains 81 and 82 (Figs. 9 and 10) and 90 (Fig. 11) have the advantage that these elements are poor heat conductors due to the fact that their links are only connected to each other by practically point-shaped contact.

The described container comprises an inner casing 20 which is practically controlled along its walls by means of cubes 30 and by chains, the control of the inner casing

20 in the example shown and described occurs along

the center lines that converge in fixed points. It is clear from this arrangement that when expansions and contractions occur during operation, the flat walls of the inner casing 20 will contract or expand while they practically remain in their respective planes. Deformations of the mantle due to temperature changes practically occur along the edges or the rounded corners of the inner mantle, the center point of each surface forming practically the only fixed point.

The schematic section in fig. 12 shows by means of the line h.o. the horizontal plane in which the upper surface 26 of the inner shell lies, and by means of the line o, v the vertical plane in which in practice the wall 24 of the inner shell 20 lies. The curve 90 shown with a fine line touching the axes o h and o v shows the position taken by the rounded edge of the mantle when this mantle expands and the dash-dotted line 91 shows the rounded edge of the inner mantle 20 after the contraction. It can be seen that the compensation of the contraction or expansion of the inner jacket takes place practically by a change of the radius of curvature of the cylindrical flexible part of the container. What is stated here regarding the surfaces 24 and 26 in the inner mantle obviously also applies to the other surfaces in those in fig. 1 and 2 showed embodiments. Advantageously, the corners of the room 10 will be filled with finely divided insulating material comprising elastic elements, so that the insulating material in these corners always fills the entire available space.

In order to prevent a collapse of the edges and the rounded corners in the container bottom located between the vertical walls 22, 23, 24 and 25 and a collapse of the bottom 27 in the inner casing, the latter casing can be supported at its bottom from points such as lies in a horizontal plane parallel to the bottom 27 in the mantle 20.

Fig. 13 shows with the dashed line 95 and the connecting line between the flat vertical walls and the lower cylindrical surfaces of the inner casing on which supports 96 are arranged. These supports 96 are mounted on insulating blocks 97 which rest on the bottom 17 of the container . They are of course immersed in the finely divided insulation material which is placed at the bottom of the container. It will be understood that in this embodiment it is the bottoms of supports 96 that form the fixed points from which the contractions or expansions of the mantle act on other fixed points representing the points at which the center lines of the upper and lower surfaces of the inner mantle 20 meet each other .

An arrangement of insulating cubes and powdered insulating material is described above, whereby the insulating cubes are arranged in a zigzag pattern. Fig. 14 shows an embodiment where the insulating cubes are arranged vertically flush with the vertical wall 100 in a room. Such an arrangement of cubes 101 in a vertical plane and the presence of insulating powder at 102 between two vertical rows of cubes enables a special shape of the inner mantle which comprises planar sections at 103 at the rows of cubes 101, and cylindrical sections at 104 between neighboring rows. Such a device can have advantageous mechanical properties with regard to the resistance of the container in use.

In order to provide a container for the storage and transport of liquefied gas at low temperatures, plates of special steel are used, the thickness of which is a few cm. The construction according to the invention allows stiffening or reinforcing members to be looped, but it is clear that the use of such stiffening or reinforcing members which cooperate with the fixed insulating elements arranged in the space between which the mantle is placed will allow a significant reduction in the thickness of the plates used.

In the embodiment shown in fig. 15 and 16, it is, as shown in the ground plan in fig. 15, arranged bracing elements with a small cross-section. They are attached to the outer surface of the casing by means of welding points near their central part, or they are held in place by means of braces to allow free expansion relative to the casing. One can also arrange bracing profile parts on the inner surface of the casing and provide uninterrupted and sufficiently resistant welding points to prevent the casing from coming loose.

If fig. 15 is considered in more detail, it can be seen that two types of stiffening elements are welded to the mantle plates (not shown), on the one hand stiffening elements which are designed as rectilinear elements which form profile parts with a small cross-section, such as stiffening elements 110, 111, 112, 113 and 114, and on the other, elements that are cross-shaped, such as the middle bracing element in fig. 15 denoted by 115. In fig. 15, by means of small thick lines, schematically shows welding points by means of which the stiffening elements 110-115 are attached to the mantle (not shown). As shown in the drawing, the ends of the bracing elements are indifferent whether they form linear segments or whether they are cross-shaped, arranged regularly around the center of cubes 116 arranged in a zigzag pattern in the space between the mantle in the container and the wall of the room, the hatch or the like in which the container is placed.

Fig. 16 which is a section along the line 16-16 of fig. 15 shows a cube 116 arranged between the wall 117 in the container jacket and the wall 118 in the room in which the container is placed.

At 119, the powdered or granulated insulating material is shown in the space between the mantle 117 and the wall of the room 118. The block that forms the cube 116 preferably consists of balsa wood or "cladding cell" which has excellent insulating properties. In order to prevent the cubes 116 of fragile material from being destroyed in contact with stiffening elements, such as 114 and 113 in fig. 16, the surface in contact with the bracing elements is covered with a hard wood panel 116a. It is in fig. 16 the means used to hold the dice 116 in place in the space are not shown, but it will be understood that the various embodiments described above can be used here.

In the one in fig. 17 and 18, there is a preferably uninterrupted floor consisting of planks 121 of impregnated wood, e.g. with a thickness of 2-3 cm. On the floor 121 are riveted or stuck on blocks with a thickness of a few cm, these blocks with the surface that lies directly opposite the surface supporting the floor 121, rest against cubes 122 arranged in the space between the inner mantle 120 of the container and the partition wall in the room.

As shown in fig. 17, where, for the sake of clarity, neither the wall 120 nor the floor 121 is shown, three types of barriers are arranged there: namely short barriers 123, medium-long barriers 124, and long barriers 125. As far as resistance is concerned, this device has the same properties as the device of bracing elements shown in fig. 15. In the same way as with the one in fig. 15 and 16, a plate of wood or another hard insulating material 126 is arranged on the surface of the block 122 that is in contact with the rafters, which protects the surface of the block 122 in contact with the rafters.

According to one embodiment, it is possible to attach the rafters not to the floor 121, but to the blocks 122. In this case, the floor 121 can also simply be looped.

It will be understood that the above-described device makes it possible, when using reinforcing members formed from hard wood with a total thickness of 10 cm, to obtain a framework by means of which the cubes can be removed from each other, and at the same time ensure a sufficient engagement of the spacers on the walls of the container casing.

In the one in fig. In the embodiment shown in 19 and 20, the dice are completely looped. The flat walls in the container are held here firmly in relation to the walls in the room by means of struts which form mutually parallel planks with a cross-section of e.g. 15 x 5 cm. or 10 x 5 cm. The distance elements then consist of beams of poorly conductive material, e.g. of hard wood, in that the beams that lie in the same plane are parallel to each other and cross beams that lie on adjacent planes, so that a lattice-shaped network is formed. Fig.

19 and 20 show a device consisting of four

plan comprising parallel rows of stirrups or planks. Fig. 19 shows planks abutting the mantle (not shown) denoted by 130, and planks in the immediately following layer denoted by 131. In that in fig. 20 example, four successive plank layers 130, 131, 132 and 133 are arranged. The plank layer 130 is preferably attached to the floor 134 which rests on the flat surface 135 of the mantle, and the planks 133 are firmly connected to a floor 136 which rests on the flat wall 137 in the room. Suitable spacers or fasteners are arranged to connect the planks in the layers 131 and 132. It will be understood that with such an arrangement the planks 130-133 will during the expansions or contractions thereof. in-

The reversible containers could easily be moved relative to each other.

According to an embodiment not shown, it is possible to arrange a joint connection between the planks at their crossing points.

It must be mentioned, especially with regard to fig. 17 and

19, that the angle of inclination relative to the vertical line

of the beams used should be such that the powdered or granulated insulation material

which is introduced in the space between the mantle and the wall in the room fills in all spaces

between the different distance elements.

It must also be mentioned that it is possible with it

on fig. 19 and 20 showed the embodiment to be arranged

a different number than four of the plank layers lying on top of each other, and that the floors can be looped

134 and 136 or one of them.

Claims (2)

1. Container for storage and transport of liquefied gas at a very low temperature, such as liquefied methane, which container comprises an inner jacket of essentially parallelepiped shape with cylindrical corner edges - and rounded top placed in a rigid, mainly parallelepiped space, in that the inner mantle is intended to contain the liquefied gas and its dimensions are only slightly smaller than the dimensions of the space, characterized in that the walls of the inner mantle (20, 120) are thin, flexible and smooth and are in and of themselves known manner supported by intermediate elements (30, 32, 40, 50, 60, 101, 116, 121—122, 130, 131, 132, 133, 134, 136) of solid insulating material, which are immovably attached to the rigid room ( 10) inner walls, as the intermediate elements provide each of said mantle's (20, 120) planar walls with a so-called continuous planar support surface, so that said mantle's expansions and contractions induce displacement of its planar walls on their respective support surfaces and are absorbed by variation of the arc of the corner edges and the arc of the rounded tops, which for this purpose have a large radius. 2. Container according to claim 1, characterized in that the inner mantle (20) on its side walls (22, 23, 24, 25), upper wall (26) and lower wall (27) comprises angle pieces, profiles or the like (70) arranged in a cross preferably mainly along the center lines or diagonals of the walls, as the angle pieces can slide on or in a guide path (71) arranged in some of the said intermediate elements, so that the crossing points for said center lines or diagonals form fixed points during the expansion and contraction of the corresponding walls. Cited publications: Norwegian patent no. 97 048, 99 889. British Patent No. 851,568, 855,520, 864,150. German inside. writ No. 1,083,288, 1,088,992, 1,096,232, 1,111,050, 1,126,272. U.S. Patent Nos. 2,513,749, 2,863,297, 3,071,094.