KR102227889B1 - Insulation Panel of Membrane Type Tank and Method of Manufacturing that - Google Patents

Abstract

The present invention relates to a method of manufacturing an insulating panel comprising a first partial panel composed of a plurality of unit panels and including a first insulating material, and a second partial panel in which a protective plate is adhered to one side of an uncut second insulating material. In the above, (a) applying an adhesive to the exposed surface of the second insulating material to which the protective plate is not adhered in the second partial panel; (b) placing the first partial panel on top of the second partial panel; And (c) the first partial panel is firmly fixed to the upper portion of the second partial panel by an adhesive; and (b), in step example, stress concentration due to heat contraction occurring in the insulating panel in the first partial panel A slit is formed to alleviate the slit, wherein the slit is formed by an arrangement interval of a plurality of unit panels constituting the first partial panel. It provides a method of manufacturing an insulation panel for a membrane-type storage tank.

Description

Insulation Panel of Membrane Type Tank and Method of Manufacturing that}

The present invention relates to a method of manufacturing an insulation panel for a membrane storage tank, and more particularly, by preventing the load from being concentrated at the end of the slit formed in the insulation panel constituting the insulation layer of the membrane storage tank, It is about the manufacturing method of the insulation panel of the membrane type storage tank that secures the stability against the air.

Natural gas is transported in gaseous form through gas pipelines on land or sea, or stored in LNG carriers in the form of liquefied natural gas (LNG) and transported to remote consumers. LNG is obtained by cooling natural gas to cryogenic temperatures (approximately -163°C), and its volume is reduced to approximately 1/600 compared to that of gaseous natural gas, so it is very suitable for long-distance transportation through sea.

Storage tanks that can withstand the cryogenic temperatures of LNG (commonly referred to as'cargo holds') are installed in structures for transporting or storing LNG, such as LNG carriers for loading and unloading LNG to land-required destinations by operating the sea with LNG.

LNG storage tanks can be classified into Independent Tank Type and Membrane Type, depending on whether the load of cargo directly acts on the insulation material. Usually, the membrane type storage tank is divided into GTT's NO 96 type and MARK Ⅲ type, and the independent tank type storage tank is divided into MOSS type and IHI-SPB type.

Membrane storage tanks are insulating systems of a double barrier structure, and are provided with primary and secondary sealing walls made of metal membranes, and primary and secondary insulating layers supporting them, respectively.

The primary and secondary insulation layers are in the form of an insulation box filled with insulation such as perlite powder or glass wool inside a plywood box, depending on the type of storage tank, or poly It can be provided in the form of an insulation panel in which plywood plywood is adhered to the upper, lower, or both upper and lower surfaces of a polyurethane foam.

1 is a view showing a conventional heat insulating panel constituting the heat insulating layer of a membrane-type storage tank, Figure 2 is a view for explaining the problem of the conventional heat insulating panel.

1 and 2, the conventional insulation panel 10 is manufactured in the form of a sandwich panel by attaching a plywood 12 made of plywood to the upper and lower surfaces of the insulation 11 made of polyurethane foam. In this case, a slit 13 may be formed on the top of the insulation panel 10 in order to relax heat shrinkage generated in the insulation layer due to thermal load.

The slit 13 is mechanically processed to the required depth after the conventional insulation panel 10 is manufactured as a sandwich panel-type insulation layer, and accordingly, the end of the slit 13 formed in the insulation panel 10 ( 13e) is provided with the polyurethane foam exposed.

However, according to the conventional heat-insulating panel 10 structure, when heat contraction occurs due to a thermal load on the heat-insulating panel 10, a force to contract to the center of each slit 13 is generated, whereas the slit end 13e Loads in different directions between the widths of the slit 13 may occur, resulting in a phenomenon in which stress is concentrated, which may limit the design of the heat insulating layer to increase the safety factor.

In addition, in the conventional thermal insulation panel 10, since the slit 13 is processed by machining equipment such as a cutting tool (for example, a saw), the width of the slit 13 is determined according to the width of the cutting tool. If the space of 13) cannot be separately filled, convection occurs in the space of the slit 13, which may be a factor that hinders the heat insulation effect.

In order to solve the above problems, the present invention prevents the load from being concentrated at the end of the slit formed in the insulation panel constituting the insulation layer of the membrane-type storage tank, thereby manufacturing an insulation panel that secures stability against thermal load. It is a technical challenge to provide a method.

In addition, the present invention is another technical problem to provide a method of manufacturing an insulating panel capable of minimizing the loss of the insulating effect by reducing the width of the slit formed in the insulating panel.

In order to achieve the above object, the present invention is a first partial panel consisting of a plurality of unit panels and including a first insulating material, and a second partial panel in a form in which a protective plate is adhered to one side of the uncut second insulating material. A method of manufacturing an insulating panel comprising: (a) applying an adhesive to an exposed surface of a second insulating material to which a protective plate is not adhered in the second partial panel; (b) disposing a first partial panel over the second partial panel; And (c) firmly fixing the first partial panel on the upper portion of the second partial panel by the adhesive, and, in the step (b), occurring in the insulating panel on the first partial panel. A slit is formed to alleviate the concentration of stress due to thermal contraction, wherein the slit is formed by an arrangement interval of the plurality of unit panels constituting the first partial panel. Provides a method of manufacturing.

The adhesive may be used that has a relatively superior strength upon curing than the first and second insulating materials.

The first and second heat insulators are glass fiber reinforced polyurethane foam, and the adhesive may be made of an adhesive material having a strength of 2 to 20 times higher than that of the glass fiber reinforced polyurethane.

In addition, another aspect of the present invention for achieving the above object is, in a method of manufacturing a heat insulating panel in which a slit is formed in at least one of an upper and a lower portion in order to alleviate the stress concentration due to heat contraction, the heat insulating panel is raised It is configured by dividing into a plurality of partial panels whose layers are divided along a direction, but by providing at least one of the plurality of partial panels as a plurality of unit panels so that the slit is formed by the arrangement intervals of the plurality of unit panels, The plurality of partial panels facing each other provides a method of manufacturing an insulating panel for a membrane-type storage tank, characterized in that bonding with an adhesive having a relatively higher strength than the insulating material constituting the insulating panel.

According to the present invention, even if the stress is concentrated due to the heat shrinkage caused by the heat load in different directions based on the slit formed in the insulating panel, the adhesive applied to the adhesive surface between the layers composed of the upper panel and the lower panel As a result, resistance at the ends of the slit is increased, and accordingly, stability at the slit and slit ends is secured against the concentration of load due to discontinuity of the heat insulating layer.

Therefore, the present invention can see a reinforcing effect on the stress concentration generated at the end of the slit due to heat contraction due to thermal load, and there is an effect of increasing the safety factor in the design of the heat insulating layer.

In addition, according to the present invention, since it is possible to freely form the slit formed in the heat insulation panel at a specific interval, there is an effect of minimizing heat insulation loss by providing a minimum width of the slit.

1 is a view showing an insulation panel of a membrane-type storage tank according to the prior art
Figure 2 is a view for explaining the problem of the conventional insulation panel
3 is a view showing the insulation panel of the membrane-type storage tank according to the present invention
Figure 4 is a side view of the insulation panel shown in Figure 3
5 is a view showing an insulation panel of a membrane-type storage tank according to another embodiment of the present invention
6 is a view sequentially showing the steps of manufacturing the insulation panel of the membrane-type storage tank according to the present invention

In order to fully understand the present invention, operational advantages of the present invention, and objects achieved by the implementation of the present invention, reference should be made to the accompanying drawings illustrating preferred embodiments of the present invention and the contents described in the accompanying drawings.

Hereinafter, the present invention will be described in detail by describing a preferred embodiment of the present invention with reference to the accompanying drawings. The same reference numerals shown in each drawing indicate the same members.

In the present invention, in a membrane-type insulation system for a cargo hold of a liquefied gas carrier or a liquefied gas fuel container, a membrane made of a metal material usable at cryogenic temperatures is used as the primary and secondary sealing walls, and the primary and/or secondary insulation layers are used. It relates to a system including a constituting insulation panel (insulation panel) as a component.

3 is a view showing the insulation panel of the membrane-type storage tank according to the present invention, FIG. 4 is a side view of the insulation panel shown in FIG. 3, and FIG. 5 is a thermal insulation of the membrane-type storage tank according to another embodiment of the present invention. It is a diagram showing the panel.

First, referring to Figures 3 and 4, the heat insulating panel 100 according to the present invention, the upper protective plate 112 and the lower protective plate 122 on the upper and lower surfaces of the insulating materials (111, 121) made entirely of glass fiber reinforced polyurethane foam. ) Is attached and manufactured in the form of a sandwich panel, and it is composed by dividing the layers into an upper part panel (110) and a lower part panel (120).

Specifically, the upper partial panel 110 includes an upper insulating material 111 and an upper protective plate 112 attached to the upper surface of the upper insulating material 111, and the lower partial panel 120 is a lower insulating material 121 and a lower insulating material It includes a lower protective plate 122 attached to the lower surface of (121).

The upper and lower insulating materials 111 and 121 may be made of glass fiber reinforced polyurethane foam, and the upper and lower protective plates 112 and 122 are composite materials such as plywood or glass reinforced plastic (GRP). materials) can play a role of imparting mechanical stiffness to the heat insulators 111 and 121.

In addition, the upper partial panel 110 includes a slit 113 formed to relieve stress concentration due to heat contraction generated in the heat insulating layer due to thermal load.

The slit 113 is provided to avoid a stress concentration phenomenon caused by a load generated in the heat insulating layer, particularly a thermal load, and is shown to be formed only on the upper part panel 110 side, but the lower part panel 120 It may be formed in the upper portion panel 110 and the lower portion panel 120 may be formed on both.

Hereinafter, for convenience of description, the formation of the slit 113 in the upper partial panel 110 will be described with reference to the drawings.

As for the slit 113, an arrangement structure such as a depth or a spacing between the slits 113 is determined according to the size of the heat insulating layer, the connection of the membrane, and the connection structure between the heat insulating layer and the heat insulating layer.

The slit 113 may be formed in a single or multiple pieces along the length direction and/or the width direction of the insulation panel 100 constituting the insulation layer, and when provided in both the length direction and the width direction, the slit 113 may be formed along each direction. The formed slits 113 are orthogonal.

As described above, the present invention is due to the discontinuity of the heat insulation layer generated by the slit 113 formed in the heat insulation panel 100, the load is concentrated on the slit 113 or the slit end (113e), resistance by the design load It is trying to solve a problem that may be inferior to this other part.

To this end, the present invention is a plurality of the upper insulating material 111 and the lower insulating material 121 by the upper part panel 110 and the lower part panel 120 in place of the insulating material 11 (FIG. 1) provided as a single layer. Divided into layers of, but the plurality of layers are bonded by an adhesive 130 having a higher strength than the insulation materials 111 and 121, and the position of the side to which the plurality of layers are bonded is formed on the upper insulation material 111 Matched to the end 113e of the slit 113 or provided lower than the slit end 113e.

In the heat insulating panel 100 according to the present invention, the resistance at the end 113e of the slit 113 is increased by the adhesive 130 bonding between the upper insulating material 111 and the lower insulating material 121, and thus Accordingly, there is an effect of securing stability at the slit 113 and the slit end 113e with respect to load concentration due to discontinuity of the heat insulating layer.

The adhesive 130 has a relatively higher strength than the upper and lower insulating materials 111 and 121, and has a higher strength when cured than the glass fiber reinforced polyurethane foam constituting the upper and lower insulating materials 111 and 121. It can be provided with an adhesive material that is at least twice as large as 20 times as large.

On the other hand, the insulation panel 100 according to the present invention is not a method of machining the slit 13 (FIG. 1) after manufacturing the insulation layer in the form of a sandwich panel as in the prior art (see FIG. 1), but the upper insulation material 111 And the upper part panel 110 made of the upper protection plate 112 is composed of a plurality of unit panels (110u), and the upper part of the lower part panel 120 made of the lower insulation material 121 and the lower protection plate 122 By adjusting the spacing of the plurality of unit panels 110u and disposing the plurality of unit panels 110u, the spacing itself formed by the plurality of unit panels 110u may form the slit 113.

The plurality of unit panels 110u constituting the upper partial panel 110 are individually manufactured as a plurality of unit panels 110u with plywood or composite material attached to the upper surface, or are manufactured as a single panel and then a plurality of unit panels 110u are formed. It may be provided in such a way that it is cut into the unit panel 110u.

As described above, the insulation panel 100 according to the present invention may have a slit at the bottom, which is by changing the positions of the upper panel 110 and the lower panel 120 in the above embodiment. Can be derived.

In addition, as shown in FIG. 5, the insulation panel 100 according to another embodiment of the present invention may be configured to have slits 113 and 123 formed in both upper and lower portions. Such a structure may be derived by providing the lower partial panel 120 as a plurality of unit panels, similarly to the upper partial panel 110, and forming slits 123 at intervals between the unit panels.

In the embodiment shown in FIG. 5, the insulating panel 100 is composed of three layers by adding an uncut middle panel 140 between the upper panel 110 and the lower panel 120, It would be desirable for the purposes of the present invention to implement the adhesive 130 on the upper and lower surfaces of the middle panel 140. The middle panel 140 may be formed of only an insulating material made of glass fiber reinforced polyurethane foam.

6 is a view sequentially showing the steps of manufacturing the insulation panel of the membrane-type storage tank according to the present invention. Hereinafter, a method of manufacturing an insulating panel for a membrane-type storage tank according to the present invention will be described with reference to FIG. 6.

In the method of manufacturing the insulation panel 100 of the membrane-type storage tank according to the present invention, first, as shown in FIG. 6 (a), the lower protective plate 122 is formed on the lower surface of the uncut lower insulation material 121 It starts from the step of preparing the lower part panel 120 of the bonded form.

Next, as shown in (b) of FIG. 6, a step of applying the adhesive 130 to the exposed surface of the lower insulating material 121 in the lower partial panel 120 is performed.

In addition, the present invention includes the step of preparing the upper partial panel 110 provided with a plurality of unit panels 110u, as shown in (c) of FIG. 6. As described above, the upper partial panel 110 is individually manufactured as a plurality of unit panels 110u with plywood or composite material attached to the upper surface, or as a plurality of unit panels 110u after being manufactured as a single panel. It can be prepared in such a way that it is cut.

In this embodiment, the step of preparing the upper partial panel 110 may be performed prior to the step of applying the adhesive 130.

Finally, as shown in (d) of FIG. 6, after the step of disposing the upper part panel 110 provided with a plurality of unit panels 110u on the upper part of the lower part panel 120, the upper part Since the panel 110 is firmly fixed to the lower panel 120 by the adhesive 130, the manufacture of the insulation panel 100 according to the present invention can be completed.

In the step of arranging the upper partial panel 110, the slit 113 may be formed by the gap formed by the unit panels 110u by adjusting and disposing the space between the plurality of unit panels 110u.

If the configuration and arrangement order of the upper panel 110 and the lower panel 120 are reversed in the series of processes as described above, it will be possible to form the slit at the lower portion of the insulating panel 100 instead of at the upper portion.

In addition, in the above process, if the lower part panel 120 is also provided as a plurality of unit panels and a step of forming slits at intervals between the unit panels is further added, a configuration diagram of forming slits in both upper and lower portions of the insulating panel 100 You will be able to derive it.

According to the present invention, the end (113e) of the slit 113 formed in the insulation panel 100 is not exposed to the glass fiber-reinforced polyurethane foam, but is made of an adhesive 130 having strong strength compared to the glass fiber-reinforced polyurethane foam. In the form of contacting (or almost in contact with) the formed adhesive surface, even if the stress is concentrated due to heat contraction caused by the thermal load in different directions based on the slit end 113e, the safety factor in the design of the insulation layer is reduced by the adhesive 130. It can have a heightening effect.

In addition, the present invention freely forms the width of the slit 113 at a specific interval by adjusting the spacing of the plurality of unit panels 110u when the upper part panel 110 is disposed on the upper part of the lower part panel 120 It is possible, and by providing a minimum width of the slit 113 can have an advantage in terms of the heat insulation effect of the heat insulation panel (100).

The present invention is not limited to the disclosed embodiments, and it is obvious to those of ordinary skill in the art that various modifications and variations can be made without departing from the spirit and scope of the present invention. Therefore, such modifications or variations will have to belong to the scope of the claims of the present invention.

100: insulation panel
110: upper part panel
111: upper insulation
112: upper protective plate
113: slit
120: lower part panel
121: lower insulation
122: lower protective plate
130: adhesive

Claims (11)

In the manufacturing method of the insulation panel installed as a component of the primary insulation layer or the secondary insulation layer of a membrane storage tank,
The insulating panel includes a first partial panel including a first insulating material, and a second partial panel in which a protective plate is adhered to one side of the uncut second insulating material, wherein the first partial panel and the second The partial panels are configured to form different layers,
(a) applying an adhesive to the exposed surface of the second insulating material to which the protective plate is not adhered to the second partial panel;
(b) disposing a first partial panel on the exposed surface; And
(c) firmly fixing the first partial panel to one surface of the second partial panel by the adhesive; including,
In the step (b), a slit is formed in the first partial panel to relieve stress concentration due to heat contraction occurring in the heat insulating panel, and the slit has an end between the first partial panel and the second partial panel. Characterized in that located on the adhesive side of,
Method of manufacturing insulation panels for membrane storage tanks. The method according to claim 1,
The first partial panel is divided into a plurality of unit panels,
The slit is characterized in that formed by the arrangement interval of the plurality of unit panels,
Method of manufacturing insulation panels for membrane storage tanks. The method according to claim 1,
The adhesive is characterized in that using the one having a relatively superior strength upon curing than the first heat insulator and the second heat insulator,
Method of manufacturing insulation panels for membrane storage tanks. In the manufacturing method of the insulation panel installed as a component of the primary insulation layer or the secondary insulation layer of a membrane storage tank,
The insulating panel is configured by dividing it into a plurality of partial panels whose layers are divided along the height direction, and the surfaces of the plurality of partial panels facing each other are adhered with an adhesive having a relatively higher strength than the insulating material constituting the insulating panel,
In order to alleviate the concentration of stress due to heat contraction occurring in the heat insulating panel, a slit is formed on one or more of the plurality of partial panels, and the ends of the slit are adhesive formed on the surfaces of the plurality of partial panels facing each other. Characterized in that located on the side,
Method of manufacturing insulation panels for membrane storage tanks. The method of claim 4,
A partial panel in which the slit is formed among the plurality of partial panels is provided as a plurality of unit panels, and the slit is formed according to an arrangement interval of the plurality of unit panels,
Method of manufacturing insulation panels for membrane storage tanks. In the insulation panel installed as a component of the primary insulation layer or the secondary insulation layer of the membrane-type storage tank,
The insulation panel is divided into a plurality of layers including an upper part panel and a lower part panel, and
The upper part panel and the lower part panel are attached by an adhesive, so that an adhesive surface to which the adhesive is applied is formed between the upper part panel and the lower part panel,
For the purpose of alleviating stress concentration due to heat contraction occurring in the heat insulating panel, a slit is processed along the thickness direction of the panel in at least one of the upper part panel and the lower part panel,
Characterized in that the end of the slit is located on the adhesive surface,
Insulation panels for membrane storage tanks. The method of claim 6,
A panel in which a slit is formed among the upper and lower panel panels is divided into a plurality of unit panels, and the slit is formed by an interval formed by the plurality of unit panels,
Insulation panels for membrane storage tanks. In the insulation panel installed as a component of the primary insulation layer or the secondary insulation layer of the membrane-type storage tank,
The insulating panel is divided into a plurality of layers, including an upper partial panel and a lower partial panel, and an intermediate partial panel disposed between the upper and lower partial panels,
The upper part panel and the lower part panel are attached to both sides of the middle part panel by adhesives, respectively, so that a first adhesive surface is formed between the upper part panel and the middle part panel, and the lower part panel and the A second adhesive surface is formed between the middle part panels,
For the purpose of alleviating the concentration of stress due to heat contraction occurring in the insulating panel, slits are respectively processed in the upper and lower panel, and the end of the first slit formed in the upper panel is the first Located on the adhesive surface, characterized in that the end of the second slit formed on the lower part panel is located on the second adhesive surface,
Insulation panels for membrane storage tanks. The method of claim 8,
The upper partial panel is divided into a plurality of first unit panels, and the first slit is formed by an interval formed by the plurality of first unit panels,
The lower part panel is divided into a plurality of second unit panels, and the second slit is formed by an interval formed by the plurality of second unit panels,
Insulation panels for membrane storage tanks. The method according to claim 6 or 8,
The upper part panel and the lower part panel comprise an insulating material made of polyurethane foam, and the adhesive has a relatively superior strength when cured than the heat insulator,
Insulation panels for membrane storage tanks. The method of claim 10,
The insulating material is a glass fiber reinforced polyurethane foam,
The adhesive is an adhesive material having a strength of 2 to 20 times that of the glass fiber reinforced polyurethane foam when cured,
Insulation panels for membrane storage tanks.

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