RU2526870C1 - Heat-insulating sealed wall of reservoir made of polymeric composite materials for compressed natural gas - Google Patents

Abstract

FIELD: transport.

SUBSTANCE: heat-insulating sealed wall of reservoir for compressed natural gas consists of blocks fixed on vessel hull using mechanical fixture which blocks include primary and secondary heat-insulating panels, primary sealing layer fixed on the blocks and secondary sealing layer located between them. The blocks are interconnected using bands of sealing layers, as well as heat-insulating materials placed in gaps between blocks. Wall blocks have forming coverage from all sides made of polymeric composite materials creating enclosed volume simultaneously surrounding primary and secondary heat-insulating panels. The blocks include primary sealing layer which is made of flexible material and attached directly to panels by means of sticking primary heat-insulating panel on the outside of forming coverage with partial transition to secondary heat-insulating panel forming coverage. In this structure, gaps between block panels are closed by bands of corresponding sealing layer which bands are attached to panels by sticking on portions of primary sealing layer at panel edges.

EFFECT: lowering labour consumption during manufacturing and assembling reservoir in vessel hull, lowering reservoir mass while increasing design reliability and its heat-insulating properties.

7 cl, 4 dwg

Description

The invention relates to the field of shipbuilding and relates to the creation of tanks for transporting liquid cargo and liquefied gases in containers with thermal insulation.

A known design of a sealed thermally insulated tank, built into the supporting structure of the ship’s hull, consisting of blocks attached to the hull of the vessel by mechanical fastening and including primary and secondary heat-insulating panels, a primary sealing layer of metal in contact with the transported cargo, fixed to the blocks by welding to block supports, and a secondary sealing layer located between the panels. The blocks are interconnected using strips of sealing layers and thermal insulation materials placed in the gaps between the blocks (United States Patent, No. 5586513, B63B 25/16, Dec. 24, 1996) - prototype.

However, the prefabricated blocks that make up the container do not directly include the primary sealing layer, so laborious welding of the sealing layer in the hull is required.

In addition, reinforcing the heat-insulating material with fiberglass is used in the design of heat-insulating panels, which impairs its heat-insulating properties and increases its mass.

The fastening of the secondary sealing layer and massive heat-insulating panels to each other is carried out using an adhesive, which can reduce the reliability of the design of the vertical walls and the roof of the tank, especially in case of damage to the primary sealing layer.

The objective of the invention is to reduce the complexity of the production and assembly of containers in the hull while improving the reliability of the structure and improving its thermal insulation properties.

This is achieved by the fact that the known heat-insulating hermetic wall of the tank for liquefied natural gas consists of blocks fixed by mechanical fastening on the ship’s hull, including primary and secondary heat-insulating panels, a primary sealing layer fixed to the blocks and a secondary sealing layer located between them. The blocks are interconnected using strips of sealing layers and placed in the gaps between the blocks of thermal insulation materials. According to the invention, its blocks have a single molding on all sides of polymer composite materials (PCM), forming a closed volume, simultaneously covering the primary and secondary thermal insulation panels. The blocks include a primary sealing layer attached directly to the panels by sticking it on the outside to form the primary insulation panel with a partial transition to the molding of the secondary insulation panel. The gaps between the panels of the blocks are closed by strips of the corresponding sealing layer attached to the panels by sticking them on the areas of the primary sealing layer at the edges of the panels.

In addition, on the inner side of the tank wall there is a PCM layer formed on the primary sealing layer of the primary heat-insulating panel and on its strips.

In this case, the primary and secondary heat-insulating panels have individual PCM moldings on all sides, and the secondary sealing layer is glued between the specified moldings of the primary and secondary heat-insulating panels.

Sealing strips covering the gaps between the panels of the blocks are glued so that they are in the gaps below the surface of the panels by 0.03-0.08 of the strip width within the gap of the corresponding sealing layer.

In thermal insulation panels, low-density foam or bulk materials, such as perlite, are used as heat-insulating material.

The mechanical fasteners of the blocks to the hull of the vessel are lugs welded to the hull of the vessel and studs fixed on them, passed through the gaps between the panels of the blocks and equipped with a clamping disk and a nut.

At the same time, the secondary thermal insulation panel has ledges for fasteners for installing blocks to the hull of the vessel.

The presence of molding blocks on all sides of the PCM, forming a single closed volume, covering the primary and secondary heat-insulating panels, increases the reliability of the design of the blocks and the walls of the tank as a whole, and the inclusion of a flexible primary sealing layer in pre-fabricated blocks glued on the outside to the molding of the primary thermal insulation panel with the transition to the molding of the secondary heat-insulating panel significantly reduces the complexity of manufacturing and assembling the tank wall.

Formed on top of the primary sealing layer of the primary heat-insulating panel and on top of its strips, the PCM sheathing layer, for example, fiberglass, increases the impact strength upon impact of the liquefied gas transported in the tank, and also acts as an additional sealing layer.

The presence of strips of sealing layers above the gaps between the blocks glued to sections of the primary sealing layer, ensure its integrity.

The design of the sealing strips covering the gaps between the panels of the blocks glued so that they are in the gaps below the surface of the panels by 0.03-0.08 of the width of each strip within the gap of the primary or respectively secondary sealing layer is necessary to create compensators for thermal and static deformations in the strip of the corresponding sealing layer.

Individual molding of PCM from all sides of the primary and secondary heat-insulating panels, forming closed structures, allows the use of a wide range of heat-insulating materials, including bulk ones, thereby improving the heat-insulating properties of the vessel wall, as well as reducing its weight and dimensions.

The essence of the alleged invention is illustrated by drawings, which show:

- a prefabricated wall block from which the heat-insulating sealed wall of the PCM container for liquefied natural gas is assembled (Fig. 1);

- cross section of a prefabricated block (figure 2);

- cross section of a prefabricated block with individual moldings from PCM primary and secondary heat-insulating panels (figure 3);

- a fragment of the cross section of the wall of the tank assembly (figure 4). The proposed heat-insulating sealed wall of a container made of PCM for liquefied natural gas includes blocks 1 (Fig. 1), consisting of primary 2 and secondary 3 heat-insulating panels, including a primary sealing layer 4 made of a flexible material, and a secondary 5 sealing layer placed between the panels and general molding 6 of RMB from all sides of the block (figure 2, 3). As the flexible material, metal foil or polymer films, for example, polyethylene terephthalate or polyimide metallized films, can be used.

Thermal insulation panels consist of a thermal insulation material, such as low density foam. They can be individually molded from PCM from all sides 7, 8 (Fig. 3), forming a closed structure, which makes it possible to use bulk heat-insulating materials, such as perlite, as the thermal insulation material of the panels. In this case, the secondary sealing layer is located between the individual moldings of the primary and secondary thermal insulation panels.

The secondary thermal insulation panel has the shape of a regular parallelepiped with ledges 9 for attachment to the hull of the vessel 10 (Fig.2, 4). The ledges are located about half the height of the vertical wall of the panel and have a width sufficient to accommodate the mounting element of the block (figure 4).

The primary thermal insulation panel is made in the form of a regular parallelepiped and is located on the upper surface of the secondary sealing layer. The panel has smaller dimensions in comparison with the secondary panel so that there is a platform on the secondary panel, the same on all sides, for fastening the strip of the secondary sealing layer 11 (Fig.2, 4).

The primary sealing layer of the block is attached to the molding using an adhesive composition and covers the entire upper horizontal surface of the primary thermal insulation panel, its sides and the horizontal area of the secondary thermal insulation panel on top of the molding, and is attached to the decoration using the adhesive composition. The blocks are fastened to the hull of the vessel (Fig. 4) using a mechanical connection, including studs 12, clamping disk 13 and nut 14. To avoid the appearance of the so-called thermal bridge, the studs are made of non-metallic materials, such as plastic. The gaps between the panels of the blocks are closed by strips 11, 15 of both sealing layers by sticking them on the areas of the primary sealing layer at the edges of the panels.

The gap between the secondary heat-insulating panels and between the studs along the panels is filled with heat-insulating material 16, for example glass wool or foam, and the gap between the primary heat-insulating panels of adjacent blocks is filled with heat-insulating material 17 in the form of foam or finished blocks. The upper surface of the insulating materials should form a flat surface, but at the same time be located below the level of the corresponding sealing layer by approximately 0.03-0.08 of the width of this layer within the gap between the panels to create a compensator for thermal and static deformations in the strip of the adhesive sealing layer.

The manufacture of a heat-insulating hermetic wall of the tank and its functioning during the transportation of liquefied natural gas are as follows.

Previously, the factory makes blocks. Heat-insulating panels are glued, PCM block is applied, onto which, within the primary heat-insulating panel, with the transition to the horizontal area of the secondary panel, the primary sealing layer is glued, and a secondary sealing layer is placed between the panels. If necessary, individual PCM moldings are also applied to the heat-insulating panels, in which the secondary sealing layer is between the primary and secondary panel moldings.

The process of manufacturing the wall of the tank includes the installation and fastening in the hull of the vessel previously made at the factory blocks using mechanical fasteners. Since the inner surface of the ship's hull has a coils, before installing the blocks it must be leveled by applying epoxy mastic rollers to the hull surface.

Previously, bosses 18 are welded to the hull in the designated places, to which the studs are attached (figure 4). After installing the blocks on the studs, clamping discs are put on, which are fixed on each stud with the clamping disc and nut.

After installing and securing the blocks, the gaps between the secondary heat-insulating panels are filled with heat-insulating material, which are then closed by strips of the secondary sealing layer. The adhesive strips are laid on the upper surfaces of the secondary heat-insulating panels over the primary sealing layer of the adjacent blocks enclosing the panel. Thus, the gap between the secondary heat-insulating panels of adjacent blocks is sealed and integrity is given to the secondary sealing layer.

Then the gaps between the primary heat-insulating panels of adjacent blocks are filled with a thermal insulation material in the form of foam or finished blocks, which are then covered with strips of the primary sealing layer by sticking them with an adhesive.

Since the upper surface of the insulating materials to be filled into the gaps between the panels should form a flat surface and be below the upper surface of the corresponding sealing layer by approximately 0.03-0.08 width of its strip within the gap between the panels, the width of the gaps between the panels of the strip blocks the sealing layer is selected taking into account this condition.

To ensure the integrity of the primary sealing layer, the sealing layers of adjacent blocks are connected. To do this, using adhesive composition, the strips of the primary sealing layer are attached to the upper surfaces of the primary sealing layers of adjacent blocks and to the surface of the thermal insulation material. The width of the strips should be greater than the distance between the panels, that is, they should overlap with the primary sealing layers of adjacent blocks. As a result of this, a continuous primary sealing layer is obtained.

At the final stage of manufacturing the container, its inner surface over the primary sealing layer is covered with PCM casing 19, for example fiberglass. This increases the impact strength upon impact of the fluid transported in the tank, and also acts as an additional sealing layer.

After assembly, the tank is filled with gas and transported. The heat-insulating hermetic wall of the tank ensures the maintenance of the required temperature of the cargo, and the sealing layer prevents its leakage during transportation.

The proposed design of a heat-insulating hermetic wall of the vessel reduces the complexity of the production and assembly of the vessel in the hull and its mass while improving the reliability of the structure and improving its heat-insulating properties, which distinguishes it from the prototype.

Claims (7)

1. A heat-insulating hermetic wall of a container for liquefied natural gas, consisting of blocks fixed with mechanical fasteners on the ship’s hull, including primary and secondary heat-insulating panels, a primary sealing layer fixed to the blocks and a secondary sealing layer located between them, and interconnected using strips of sealing layers, as well as thermal insulation materials placed in the gaps between the blocks, characterized in that the wall blocks have a single shape taste from all sides from polymer composite materials, forming a closed volume, simultaneously covering the primary and secondary heat-insulating panels, and include the mentioned primary sealing layer, which is made of flexible material and attached directly to the panels by gluing the exterior of the primary heat-insulating panel with partial transition to the molding of the secondary heat-insulating panel, while the gaps between the panels of the blocks are closed by strips of the corresponding sealing layer Attached to the panels on the label portions of the primary sealant layer at the edges of the panels. 2. The heat-insulating hermetic wall of the tank according to claim 1, characterized in that on the inner side of the wall of the tank there is a layer of polymer composite materials formed on the primary sealing layer of the primary heat-insulating panel and its strips. 3. The heat-insulating hermetic wall of the container according to claim 1, characterized in that the primary and secondary heat-insulating panels have individual moldings of polymer composite materials from all sides, while the secondary sealing layer is glued between them. 4. The heat-insulating hermetic wall of the container according to claim 1, characterized in that the sealing strips covering the gaps between the panels of the blocks are glued so that they are in the gaps below the surface of the panels by 0.03-0.08 strip widths within the gap of the corresponding sealing layer. 5. The heat-insulating hermetic wall of the container according to claim 1, characterized in that in the heat-insulating panels low-density foam or bulk materials, such as perlite, are used as heat-insulating material. 6. Thermally insulating hermetic wall of the container according to claim 1, characterized in that the mechanical fasteners of the blocks to the hull of the vessel are lugs welded to the hull of the vessel and studs are mounted on them, passed through the gaps between the panels of the blocks and equipped with a clamping disk and a nut. 7. The heat-insulating hermetic wall of the tank according to claim 1, characterized in that the secondary heat-insulating panel has ledges for mounting blocks to the hull of the vessel.

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