FR2503104A1 - VERTICAL AXIS REVOLUTION TANK ON BOARD VESSELS - Google Patents

Abstract

A method of mounting containers on board ships is proposed, which containers are designed as rotational bodies with a perpendicular axis and have in the supporting plane an outer disc ring with at least one extension on the underside, the disc ring being put on one or more cylindrical aprons and being welded to these aprons. Here, the joint area between disc ring and apron is to be prestressed uniformly and in the opposite direction to the loads to be expected in operation and resulting from dead weight and cargo weight as well as thermal stresses.

Description

 The present invention relates to improvements made to tanks of revolution with vertical axis mounted on board ships and specially intended for the transport of cryogenic liquids such as liquefied gases.

 The transport of liquefied gases by denying poses a large number of technical problems, which result mainly from the movements of the ship as well as from the low temperatures at which it is necessary to carry out the transport in the majority of cases.

This occurs, for example, in the case of natural gas (LNG) which must be transported at a pressure close to atmospheric pressure and at a temperature of around -160 C.

 One of the most reliable modes of transporting liquefied gases by sea is transport in spherical tanks, despite the difficulties presented both by the construction work and by the mode of installation of these tanks.

 Among the modes or devices for supporting and fixing spherical tanks of this type that are found on the market, one can cite the one described in Spanish Patent No. 401,774, which was invented by the applicant of this application. .

 In this patent, the operation of the structure composed of a spherical reservoir is supported continuously along its equator by a peripheral structure and support and fixing elements which will be called skirts.

 Under gravity constraints, the inner skirt works on compression while the peripheral structure and the outer skirt works on traction. Thanks to the balance established between the constraints of gravity, self-weight of the tank and liquid load, and the compression and traction forces mentioned above, the bending moments which manifest themselves in the walls of the tank, in the region of the equator, are reduced to a minimum and the thicknesses of the walls of the tank are considerably less than those of the tanks supported at their equator by a single skirt. Indeed, when the tank is supported by a single skirt, the bending moments which s 'exert in the walls of the tank and which are generated by the eccentricity between tank and skirt must necessarily be absorbed by sheets of very thick, thickness which constitutes a limitation when it comes to tanks of large diameter, because the regulatory bodies do not allow material thicknesses greater than a specified value for technological reasons.

 Regarding the thermal constraints, when the tank is A -160oC while along the support structure there is a temperature gradient (between -160 C in the upper part and the temperature in the hold of the ship in the lower part), the low rigidity of the elements of the structure of the upper part of the support and of the walls of the tank, which is a consequence of the arrangement of the double skirt, contributes to ensuring that the tensions induced, by the difference contraction between the reservoir and the support and by the curvature of the generators of the support structure, curvature which is generated by the aforementioned thermal gradient, are considerably reduced but are not completely eliminated.

 Experience has shown that the methods applied to reduce the tensions induced in the walls of the tank by thermal stresses are not very effective, including the additional reduction of the axial rigidity of the support and internal fixing element, as well as described in the first Spanish certificate of addition no. 500 005 to the aforementioned patent, in the case of spherical tanks supported by a double skirt, and certain special provisions of thermal insulation along the support structure, when the tanks are supported by one or two skirts.

 In order to eliminate said thermal voltages which are induced in the walls of spherical tanks, in the region of their equator, the invention relates to improvements made to tanks of revolution with vertical axis installed on board ships, which are specially intended for the transport of cryogenic liquids and supported by at least one continuous skirt With vertical axis and connected to the reservoir, in the equatorial region thereof, by a peripheral structure which forms part of the wall of the reservoir. before proceeding to the cooling and the first loading of the reservoir, one induces in each of the meridian sections of the peripheral structure and of the equatorial zone of the reservoir a rotation, in the plane of this section, and which is substantially identical for all the sections and opposite direction to the direction of rotation induced by the weight of the tank and its contents, which is the nieme direction in which the structu re support acts on the tank under the effect of thermal stresses.

This rotation can be of an amplitude as large as that allowed by the drawing of the peripheral structure since
the induced rotation prevents and counteracts the rotation which is generated by thermal stresses when the tank has been cooled to -160 C to be filled with LNG, but it can also be of greater amplitude and help to prevent and counter the rotation generated by the aforementioned gravity constraints, in which case it may be advantageous to oversize the peripheral structure in order to completely eliminate the bending stresses generated in the walls of the reservoir in the region of the equator, which results in a notable improvement in the behavior of the structure with regard to fatigue and the propagation of cracks, an advantage which is added to the savings made on materials, welding and specialized labor.

With regard to the production and implementation of the invention, in the case of a support structure composed of a single skirt, the upper edge of which must be joined to a continuous projection of the peripheral structure, which has already been welded to the tank, the aforementioned rotation can be induced by applying a stress distributed in the region of the upper edge of said skirt, which causes in this edge a substantially uniform rotation and in the opposite direction to the direction of rotation induced by gravity constraints and of thermal origin, the upper edge of the skirt then being welded to the projection of the peripheral structure so that, when the stress is no longer applied to the skirt, the peripheral structure and the equatorial zone of the reservoir retain a
rotation with the characteristics described above.

In the case of a support structure composed of two skirts which are spaced from one another in the radial direction, an inner skirt which works in compression and an outer skirt which works in traction, when the Equatorial zone of the tank and the inner skirt have been fitted and welded
independently, a distributed stress is applied to the outer edge of the peripheral structure which causes in said peripheral structure and in the equatorial region of the reservoir a substantially uniform rotation in the opposite direction to the direction of rotation induced by the constraints of gravity and origin thermal then performing, if this has not been done previously, the welding of the peripheral structure to the inner skirt and, in any case, thereafter, the welding of the peripheral structure to the outer skirt so that, when the constraint is no longer applied to the peripheral structure, this rotation is maintained thanks to the meridian tension which appears in the outer skirt.

Alternatively, in the case where the support structure .it composed of two skirts spaced radially from one another, d.nt one, interior, works in compression and the other, exturieure, works in traction , after mounting and welding of the equatorial zone of the reservoir and at least of the outer skirt, the middle zone of this skirt is subjected to a permanent stress which induces a deformation in the radial direction, under the effect of which this outer skirt remains subject to a meridian pull, until its upper and lower edges come together, thereby inducing in the peripheral structure and in the equatorial region of the reservoir a substantially uniform rotation and in the opposite direction to that of the rotation induced by gravity constraints and of thermal origin
Given that the application of the constraints mentioned above can be carried out in the prefabrication phase when the tank is not yet completely finished but has already been closed in its equatorial zone, the preparation costs of La structurez scaffolds, adjustment elements, jacks, etc., are very ai: 1 compared to the number of tonnes of cryogenic material that] saves on the total of the load tanks to be installed on board the LNG ship.

Other characteristics and advantages of the inventlt'n will appear during the reading of the description which will follow of an exemplary embodiment and with reference to the drawings ann, xs, on which
- Figure 1 is a partial vertical diametral section of a tank supported on two concentric skirts and constructed in accordance with the invention
- Figure 2 is a view similar to Figure 1 in which there is shown a tank supported on a single skirt; and
Figure 3 is a view similar to Figure i in which there is shown an alternative embodiment for a tank supported on two concentric skirts.

 As can be seen in FIG. 1, the tank 1 which has a spherical shape comprises a peripheral structure inserted in its wall, in its equatorial region and which, in the example shown in the drawings, consists of an equatorial profile 2, which is incorporated into the wall of the tank and which comprises, outside the tank, two projections or continuous lower ribs designated by the references 3 and 4, which are joined by welding the upper edge of two concentric skirts 5 and 6 spaced radially from one another7 which constitute the support of the reservoir. Of these two skirts, the inner skirt 5 will work in compression while the outer skirt 6 will work in traction.

 According to the inventiona after having mounted the tank, with its equatorial profile 2 welded to the wall of the tank, and the skirts 5 and 6 joined, at the bottom, to the support structure and before proceeding to the assembly by welding between the projections 3 and 4 and the upper edge of the skirts, at least before welding the external projection 4 to the upper edge of the external skirt 6, a distributed stress is applied to the peripheral structure 2 which causes in this peripheral structure and in the equatorial region of the tank a substantially uniform rotation in the opposite direction to the direction of rotation which is induced by the thermal contractions and by the weight of the tank and its contents. The application of this constraint can be obtained, for example, by means of equidistant cylinders 7 , mounted between the peripheral structure 2 and lower anchoring points 8. By adjusting the tension of these jacks, it is possible to obtain a substantially uniform rotation of the peripheral structure 2. Ap res having carried out this rotation, we proceed to the assembly - welding by welding of the upper end of the outer skirt: e (, at the external projection 4 of the peripheral structure and, possibly \ ' assembly of the upper edge of the inner skirt 5 and the projection 3.

 As is clear from FIG. 1, in order to assemble the outer skirt 6 to the projection 4, an intermediate clamp 9 can be inserted.

 After having carried out these assemblies, dn, the jacks 7 are removed, and the peripheral structure 2 and the equatorial zone of the reservoir then retain the rotation which was previously induced therein.

The rotation induced in the peripheral structure and in the equatorial zone of the reservoir can also be obtained as shown in FIG. 3, by subjecting the middle zone 10 of the internal skirt 6, after the welding of the upper edge of this skirt. at the external projection 4, at a permanent stress capable of producing a radial deformation in this part, such as that indicated in dashed line by the reference 11. In this way, the skirt remains subjected to a meridian traction and its upper and lower edges are move closer together, thereby inducing the desired rotation in the peripheral structure 2 and in the equatorial zone of the reservoir
Finally, in the case where the support for the reservoir 1 is constituted by a single skirt 12, as shown in FIG. 2, the rotation of the peripheral structure 2 and of the equatorial zone of the reservoir can be obtained, as in the case of FIG. 1, by equidistant cylinders 7 mounted around the tank between the peripheral structure 2 and lower anchors 8, all this before welding the upper edge of the skirt 12 to the single external projection 13 of the peripheral structure. After having made this desired rotation, the upper edge of the skirt of the projection 13 is welded and the jacks 7 are dismantled.

 Of course, various modifications may be made by those skilled in the art to the method and to the device which have just been described solely by way of nonlimiting example, without thereby departing from the scope of the invention.

Claims (4)

1. Tank of revolution with vertical axis installed on board a ship, specially intended for the transport of cryogenic liquids and supported by at least one continuous skirt (5, 6; 12) with vertical axis which is connected to the tank (1), in the equatorial zone of the latter, by means of a peripheral structure (2) which forms part of the wall of the tank, this tank being characterized in that, before carrying out the cooling and the first loading of the tank, one induces in each of the meridian sections of the peripheral structure (2) and of the equatorial zone of the reservoir a rotation contained in the plane of this section substantially identical in all the sections and in the opposite direction to the direction of rotation induced by the thermal contractions and by the weight of the tank and its contents. 2. Tank according to claim 1, characterized in that, in the case where each tank is supported on a single ji, pe (12) and where the peripheral structure comprises a continuous projection (13) which assembles at the upper edge of the skirt, when the equatorial zone of the reservoir (1) and the skirt (12) have been mounted and welded independently, a distributed stress is applied in the region of the upper edge of said skirt (12) which causes this rotation to rotate substantially uniform, opposite direction to that of rotation induced by thermal contractions and by the weight of the tank and its contents, and the upper edge of the skirt (12) is then welded to the projection (13) of the peripheral structure of so that, when the stress is no longer applied, the skirt, the peripheral structure and the equatorial zone of the reservoir retain a rotation in the opposite direction to that of the rotation induced by thermal contractions and by the weight of the reservoir and its contents u. 3. Tank according to claim 1, characterized in that, in the case where-each tank (1) is supported on two skirts (5, 6) spaced radially from one another, one of which is internal (5 ), works in compression and the other, external (6), works in traction, when the equatorial zone of the tank and the internal skirt have been assembled and welded independently and before the welding of the skirts to the peripheral structure (2) , a distributed stress is applied to said peripheral structure which causes in this peripheral structure and in the equatorial region of the reservoir a substantially uniform rotation, in the opposite direction to that of the rotation induced by the thermal contractions and by the weight of the reservoir and its content and then optionally welding of the peripheral structure to the inner skirt and, in any case, welding of the peripheral structure (2) to the outer skirt (6) so that, when one ceases to apply the collar ltrainta 3 the peripheral structure, said rotation is maintained thanks to the meridian tension which appears in the outer skirt. 4. Tank according to claim 1, characterized in that, in the case where each tank is supported on two skirts (5, 6), spaced radially from one another, one of which inside (5), works to compression and the other, external (6), works in traction, when the equatorial zone of the reservoir and at least the internal skirt have been assembled and welded, the central zone (10) of said external skirt (6) is subjected to a permanent stress which induces a deformation in the radial direction under the effect of which this skirt is subjected to a meridian traction and its lower and upper edges approach each other, inducing: thus in the peripheral structure and in the equatorial zone of the reservoir a rotation, substantially uniform, in the opposite direction to that which is induced by the thermal contractions and by the weight of the reservoir (1) and its contents.