NL8201380A - RESERVOIR FOR STORING LIQUEFIED GAS. - Google Patents

Description

N.0.30.831 1

Liquid gas storage container »

The invention relates to a reservoir for storing liquid gas with cylindrical casing plates and at least one reinforcement ring arranged within the casing plates.

Such reservoirs are usually under internal overpressure. However, they must be reinforced against indentation to absorb any underpressure which may occur when the reservoir is emptied and to absorb the uneven ground pressure which occurs on the outside.

Reservoirs for storing liquid in a cylindrical shape, which are surrounded by earth, are known. In order to reinforce against an internal prevailing underpressure or an externally exerted pressure, these reservoirs are usually provided with reinforcement rings arranged at certain axial distances, which are arranged in the interior space of the reservoirs and are welded to the wall of the reservoirs. At the internal pressure prevailing in the normal state, the reservoir wall - in itself considered - is expanded or stretched more than the reinforcement rings. As the reinforcement rings in the known reservoirs are welded to the reservoir wall and this prevents the reservoir wall from expanding freely, this gives rise to stresses which must be taken into account in the dimensioning of the reservoir wall and which have a relatively large plate thickness of the reservoir wall. needed.

The object of the invention is to eliminate, but at least to reduce, the stresses which are generated in the jacket plates by the connection to the reinforcement rings during expansion.

According to the invention, this object is achieved in that the casing plates enclose at least one support structure that can only be loaded under pressure. Since the support construction can only be loaded under pressure relative to the jacket plates, no tensile stresses originating from the support structure concerned can be transferred to the jacket plate when the sleeve plates are expanded, so that the total load in the jacket plates is considerably reduced. .

In an embodiment of the reservoir according to the invention, the support structure, which can only be loaded under pressure, is located within the reinforcement ring. By adding this support structure, which is preferably perpendicular (with respect to the ground surface), the forces emanating from the earth located above the reservoir are absorbed, so that the large, in the upper region of 8201380 é.

2 * the bending load occurring in the reinforcement ring is clearly reduced. The stiffening ring can therefore be dimensioned smaller than with the known reservoirs. Accordingly, the nuisance caused by the reinforcement ring when expanding the casing plates is correspondingly less. In another embodiment, the reservoir wall in the pressureless state lies flat against the reinforcement rings, while the wall can expand independently of the stiffening rings when an internal pressure occurs, without the supporting effect of the stiffening rings having to be avoided in the event of an internal one occurring underpressure, respectively, from an overpressure exerted from the outside. In this case, when the reservoir wall is expanded or stretched, practically no stresses are transferred from the stiffening rings to the reservoir wall.

In order for the stiffening rings to maintain their position in the case of an internal prevailing overpressure, the stiffening rings are mounted in axial direction loosely between two supports fastened to the casing plates.

The design of the reinforcement rings of the reservoirs, wherein the stiffening rings consist of at least two segments each provided with a baffle plate at their ends, the total circumferential length of which is slightly less than the circumferential length of the casing plates on their inner side, and wherein two segments at each end having an abutment provided on the inside offers the possibility of a simple assembly of the reinforcement rings in the ready container. A method to be described below can be used to generate the required bias of the segments. An embodiment of the reinforcement rings to be described hereinafter has the advantage that the ring segments are no longer subjected to bending to such an extent and that the cross-section thereof can thereby be kept smaller and the construction can be carried out more easily.

The invention will be explained in more detail below with reference to the drawings. In the drawings shows:

Fig. 1 a reservoir according to the invention with a reinforcement ring welded to the jacket plates and a diametrically arranged pressure support with a hollow cylindrical pressure piece in longitudinal section - with respect to the reservoir

Fig. 2 a pressure piece suitable for a tubular pressure support with a cylindrical guide part.

Fig. 40 3 a two-part pressure support with a pressure piece in perspective.

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3

Fig. 4 is a reservoir according to the invention in longitudinal section - with respect to the reservoir - with a three-segment reinforcement ring.

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Fig. 5 shows the reservoir according to FIG. 4 in section, and 5 FIG. 6 a three-segment reinforcement ring with a truss construction.

In the embodiment according to Fig. 1, the reservoir has a cylindrical jacket plate 1 into which reinforcement rings 3 'are inserted at regular intervals. Tubular compression struts 4 are attached to the lower part of the retaining rings 3f via a flange 5. To the diametrically opposite end of the flange 5 of the reinforcing ring 3 'is attached a pressure piece 6 suitable for receiving the pressure support 4. The pressure piece 6 has a flange 7 and a hollow cylindrical guide part 8 in which the pressure support 4. is inserted.

In the initial state, that is, when the reservoir is not subjected to external or internal pressure loads, the pressure support 4 is in contact with the flange 7 of the pressure piece 6. In the case of an externally exerted force - in particular from above - the flange 7 with a corresponding pressure on the pressure support 4. In the case of an internal pressure, the reinforcement ring 3 'welded to the cylindrical jacket plates 1 expands, respectively widens and the pressure piece 6 attached to the reinforcement ring 3f slides with its guide part 8 along the pressure support 4, without the pressure support 4 hindering an expansion of the reinforcement ring 3 'and of the cylindrical jacket plate 1.

In a variant of the embodiment according to Fig. 1, the pressure piece 6r in the embodiment according to Fig. 2 is equipped with a cylindrical guide part 8 which engages in the tubular pressure support 4. In Fig. 2, the associated parts are shown in the state of the stretched reservoir.

In another embodiment, the pressure support 4 'is divided in its longitudinal plane and consists of two halves, the so-called pressure parts 4a, 4b, which are supported by two pressure pieces 6' according to Fig. 2. The pressure parts 4a, 4b each have a wall 41 corresponding to a half-hollow cylinder and two flanges 42. When mounting the reservoir, the pressure parts 4a, 4b are fitted around the guide parts 8 'and the flanges 42 are screwed together so that the pressure support 4 'represents a self-rigid unit. At a corresponding internal pressure, the cylindrical casing plates and the stiffening ring (s) 40 can expand without being hindered by the pressure support 4 '

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4 third.

According to another embodiment according to Figs. 4 and 5, the reinforcement rings 3 arranged inside the cylindrical jacket plates 1 are not welded to the jacket plates 1. In order to receive or support the reinforcing rings in the axial direction, respectively, three supports 2a, 2b, 2c are mounted twice on the inside of the casing plates 1.

A reinforcement ring 3, which consists of three segments 3a, 3b, 3c, is supported between these supports 2a, 2b, 2c. Each segment has a baffle plate at each of its ends: the segment 3a the baffle plates 11, 12; the segment 3b the baffle plates 13, 14; and the segment 3c the baffle plates 15, 16. The baffle plates 12 and 13 and the baffle plates 11 and 16 are each connected by screws.

Near the baffle plates 14, 15, the segments 2b and 2c each have a stop 17 and 18 respectively. When the reinforcement rings 3 are installed in the holder, a hydraulic press 19 is arranged between the stops 17 and 18, which press the still open reinforcement ring under a presses the pretension against the inside of the jacket plates 1. The vacant space between the baffle plates 14 and 15 is filled with lining or intermediate plates 20 and the baffle plates 14, 15 and the intermediate plates 20 are firmly joined together so that the reinforcement ring 3 now forms a unit. The hydraulic press 19 is then removed from the stops 17, 18 again.

When the reservoir is filled with liquefied gas under pressure, the jacket plate 1 has the option of being able to lift freely from the reinforcing ring 3 during expansion. Conversely, the jacket plate 1 can support against the reinforcement rings in the event of an internal negative pressure.

In the embodiment of Fig. 6, segments 3a, etc.

30 each provided with a lattice consisting of several belts, bars 21 and nodes 22 connecting them, respectively. The presence of the truss makes it possible to reduce the cross-section of the segments with the same load capacity.

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Claims (7)

Liquid gas storage container with cylindrical casing plates and at least one reinforcement ring arranged within the casing plates, characterized in that the casing plates (1) have at least a support structure (3; 4, 6) which can only be loaded under pressure Enclose. Reservoir according to claim 1, characterized in that the stiffening ring or rings (3 ') are welded on the inside to the casing plates (1) and that the respective stiffening ring (3') has a pressure support arranged diametrically in its plane (4; 4 '), 10 having at least one end of a load-bearing support (6; 6') at least at one end. Reservoir according to claim 1, characterized in that the reinforcing ring or the reinforcing rings (3; 3a, ...) have a contact pressure which can only be loaded under pressure in the radial direction of the casing plates (1). Reservoir according to claim 3, characterized in that the reinforcement rings (3) are mounted loosely in axial direction between two supports (2a, ...) fastened to the jacket plates (1). Reservoir according to either of Claims 3 and 4, characterized in that the reinforcement rings (3) consist of at least two segments (3a, provided at their ends with a baffle plate (11 to 16)). 3b, 3c), the total circumferential length of which is slightly less than the circumferential length of the jacket plates (1) on their inner side, and that two segments (3b, 3c) have an internal stop (17, 18) at each end to have. Reservoir according to any one of claims 3 to 5, characterized in that the reinforcement rings (3) or the segments (3a, ...) thereof are provided with a lattice construction (21, 22). Method for mounting a reservoir according to one of claims 5 or 6, characterized in that the ends of the segments (3a, ...) - with the exception of the ends provided with stops (17, 18) - be connected to their baffle plates (12, 13; 11, 16), that the ends of the segments (3b, 3c) provided with the stops (17, 18) are pressed apart and that the distance between the outlets printed ends are filled with intermediate plates (20). ********** 8201380