KR100206257B1 - Corrugation structure for membrane of storage tank - Google Patents

Abstract

1. TECHNICAL FIELD OF THE INVENTION

The present invention relates to a corner membrane corrugation structure of a low temperature liquid storage tank.

2. The technical problem to be solved by the invention

Provides corner corrugation structure of membrane of low temperature liquid storage tank which is easy to manufacture, absorbs shrinkage and expansion amount due to temperature change and pressure change while maintaining small pressure state and short welding length.

3. Summary of Solution to Invention

The corner corrugation of the membrane is constructed to have a single corrugation, cross corrugation and a flat part.

4. Important uses of the invention

The present invention can be installed on the inner wall of the cryogenic liquid storage tank can minimize the deformation caused by the temperature change of the storage tank.

Description

Corner Corrugation Structure of Membrane of Low Temperature Liquid Storage Tank

The present invention is attached to the corner area where the wall at the side and the bottom of the inner wall of the tank for storing the cryogenic liquid such as liquefied natural gas (liquefied temperature -162 ℃) and the like meet each other liquid and gas tightness The present invention relates to a low temperature liquid storage tank corner membrane corrugation structure that simultaneously maintains the function and flexibly absorbs the contraction and expansion of the corner member due to the temperature change and pressure change caused by the injection and delivery of the storage liquid.

Conventionally, in a tank for storing cryogenic liquids, such as liquefied natural gas, a membrane as shown in FIG. 1 is installed at a corner of an inner wall connecting a side wall and a bottom wall.

Cryogenic liquid storage tank is a tank function, which requires repeated operations and maintenance such as storage liquid injection and discharge for reuse after storage of the storage liquid for a certain period of time, so that the temperature drop during injection and the temperature rise during discharge and repair are repeatedly received. .

Therefore, the membrane as shown in FIG. 1 is pre-installed in the tank side wall and bottom contacting the low temperature liquid to absorb the shrinkage and expansion caused by the temperature change.

(A) of FIG. 1 shows a structure of a side wall, a bottom wall, and a corner wall connecting the low temperature liquid storage tank used in the related art. The corner membrane 3 of FIG. 1 (a) is composed of 45 ° chamfers with a predetermined length or 90 ° corners without chamfers in order to smooth the angle of the area where the side wall and the bottom wall intersect.

A side wall membrane 1 and a bottom wall membrane 2 are installed on the side wall and the bottom wall of the low temperature liquid storage tank, and a corner membrane 3 having a cogition is also installed in advance in the corner wall contacting the low temperature liquid to change the temperature. Absorbs the amount of shrinkage and expansion. This depends on the length of the circumferential pitch 4 which depends on the tank capacity. In addition, the corner membrane 3 is subjected to the pressure head of the storage liquid and therefore must also have deformation resistance against this external force.

The corner membrane, unlike the cross-shaped membrane 6 attached to the tank side wall, only takes into account the contraction and expansion in the circumferential direction and therefore the corrugation must be arranged in the longitudinal direction. Shrinkage and expansion in the height direction decrease the longitudinal pitch in the cross-shaped membrane 6 adjacent to the corner membrane 3 to reduce the shrinkage amount in the adjacent cross-shaped membrane 6 to reduce the longitudinal pitch in the cross-shaped membrane 6. To absorb.

In FIG. 1 (b), which is one of the shapes of the conventional corrugation, the maximum stress and strain during contraction and expansion of the membrane due to temperature change are the curvature portion protruding toward the bar in the transverse direction and the end of the unitary corrugation 7. Occurs at 45 ° incline (8).

In FIG. 1 (c), which is one of the conventional corrugation shapes, the stress applied to the member during contraction and expansion of the membrane due to temperature change has the same tendency as that of FIG.

In addition, in the conventional corrugation shape as shown in FIG. 1 (d), the stress on the member during shrinkage and expansion of the membrane due to temperature change is relatively small, but the welding length is made by combining the shapes of several pieces. Longer and more expensive to manufacture.

As described above, the conventional corrugation structure has a complicated shape, and thus, in most cases, large tangential stress and bending stress are easily generated, and the manufacturing process is complicated and the welding length is long.

The present invention has been made to solve the problems of the conventional membrane corrugation structure as described above is easy to manufacture and the strength that can absorb the shrinkage and expansion amount due to temperature changes and pressure changes while maintaining a small stress state The aim of the present invention is to provide a corrugated structure of a cryogenic liquid storage tank corner membrane with improved reliability and a short welding length.

This object is achieved in the invention of two monolithic corrugations located on a plane that meets between 45 ° and 90 ° and a cross-shaped corner corrugation of the same shape as the cross-section of the single corrugation and located between the single corrugations. With reference to the accompanying drawings, which can be achieved by the corrugation structure of the low temperature liquid storage tank corner membrane according to the following.

1a, b, c, d are perspective views of a conventional membrane corrugation.

2 is a perspective view according to a preferred embodiment of the present invention.

3 is a perspective view according to another embodiment of the present invention.

4 is a perspective view according to another embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

1: side wall membrane 2: bottom wall membrane

3: corner wall membrane 4: transverse pitch

5 longitudinal pitch 6 crosswise membrane

7: single membrane 8: 45 ° inclined portion

11: single corrugation 12: cross corrugation

13: flat part

14, 14 ': part of corrugation that rises concave from the flat

15, 15 ': part of corrugation that rises concave from the top

16 concave portion 17 convex portion

18: straight part

19: cross-shaped corrugation center recess

19 ': Cross-shaped corrugation center convex

20: angle to fit the corner wall

21: single corrugation end

2 is a perspective view according to a preferred embodiment of the present invention, as shown in FIG. 2, the structure of the membrane corner corrugation according to the present invention comprises a unitary corrugation 11 formed in a single direction (YY axis direction) in the membrane; It consists of a cross-shaped corrugation 12 formed on both ends of the unitary corrugation 11 and the flat portion 13 without the corrugation.

In addition, the corrugation-free flat portion 13 and the cross-shaped corrugation 12 are configured to fit the corner wall in the shape of giving an angle 20 between 45 ° and 90 ° to position the corner membrane between the side wall and the bottom wall. And the angle 20 is configured in a rounded shape so that the curvature is made on the surface meeting each other.

The cross-sectional shape of the unitary corrugation 11 is composed of a concave rising portion 14 at both sides and a convex lowering portion 15 at an upper portion thereof, and a concave rising portion 14 and a convex lowering portion 15. ) Is formed in a shape that can include a straight line portion, and in the longitudinal direction is a shape extending to the straight portion in the cross section on one side in the longitudinal direction.

The unitary corrugation 11 has a shape in which the end portions 21 are spaced apart from each other so that the ends thereof are rounded in the same shape as the cross section. Between the ends of the unitary corrugation is a cross-shaped corrugation (12) bent at a certain angle (20).

The cross-shaped corrugation 12, which is bent at an angle 20 while having a curvature, is located at the inclined end portion of the unitary corrugation 11, and the convex portion 14 and the convex rising from the upper portion 14 are concave. Between the lower portion 15 and the portions 14 and 15, a cross section of a shape in which a straight portion may exist is bent in a shape of a shovel.

When the direction of the single-type corrugation 11 which exists in a straight line with the angle 20 on two flat planes 13 which meet 45 to 90 degrees in the curved Y direction is between each single-type corrugation end part 21, The convex portion 17, which is the outer end of the cross-shaped corrugation 12 in the 45-degree direction in the Y-axis is formed in the form of a straight portion 18 between the convex portion 17 and the concave portion 16 (18) has a shape in which the single corrugation 11 is spaced apart and spaced in parallel.

The corner 20 of the cross-shaped corrugation 12 is configured to be in contact with a rounded curvature with an angle of 45 ° to 90 ° to fit the corner where the tank side wall and the bottom wall meet.

The convex portion 17 of the cross-shaped corrugation 12 has a structure that protrudes long in a 45 ° direction with the single-type corrugation 11.

3 is another embodiment of the present invention. In another embodiment of the present invention, as shown in the drawings, the structure of the unitary corrugation 11 is a unitary corrugator that exists in a straight line on two flat planes that meet at 45 ° to 90 °. When the direction of the gating is held in the curved Y direction, a convex portion 17, which is the outer end of the cross-shaped corrugation 12 in the direction of 45 ° on the Y axis, is formed between each single corrugated end portion 21, and the single corrugated end portion (21) The recessed part 16 is formed in the inside, and is comprised by the linear part 18 between the said convex part 17 and the recessed part 16 with constant width and a shape.

Similar to the single corrugation, the cross section is concave up from both sides of the cross section and convexly descending from the upper portion, and the flat portion 19 'is formed at the upper portion as shown in FIG.

Figure 4 is a perspective view according to another embodiment of the present invention, as shown in the figure, the corrugation structure according to another embodiment of the present invention has the same structure as the embodiment of Figure 3 cross-sectional cross-section On both sides is formed in a concave up and convex down from the top and has a configuration without a flat portion on the top.

Referring to the operation of the present invention through the configuration as described above are as follows.

The low temperature liquid storage tank repeats the injection and dispensing functions, and thus the membrane attached to the inner wall of the storage tank and in direct contact with the liquid repeats the export and expansion due to the temperature rise and temperature drop due to the liquid injection, discharge and repair. . The structure of the corner corrugation of the membrane, which can absorb it while keeping it at a low stress or strain state, is an important factor affecting the stability and reliability of the tank.

Since the contraction and expansion of the corner corrugation due to the temperature change occur simultaneously in the circumferential direction, it must be suitable for the corner wall and be able to be stretched in the circumferential direction.

The corner corrugation structure of the present invention is a structure that is bent in advance so as to be able to contract and expand in the circumferential direction. Instead, the contraction and expansion in the direction perpendicular to the circumferential direction is absorbed by the cruciform membrane attached to the adjacent side wall and the bottom wall. In addition, the stress concentration effect is reduced because there is no single corrugation in the direction perpendicular to the single corrugation.

As described above, the present invention significantly improves the structure of the existing membrane corrugation to have two unitary corrugations 11 and one cross corrugation 12 on two planes meeting 45 ° to 90 °. It can be stretched in the direction to stably absorb the deformation of the membrane according to the temperature change, thereby preventing damage to the storage tank and increasing the durability of the storage tank.

In addition, both the unitary corrugation 11 and the cross corrugation 12 according to the present invention to have a large curvature as possible to prevent stress concentration. In addition, since the corrugation of the membrane according to the present invention can be easily processed by a combination of bending and drawing processing during press working, the manufacturing cost can be reduced and the welding length during installation can be reduced, thereby reducing work time.

Claims (4)

The sections 14 are arranged in the longitudinal direction on the two flat planes 13, which have a curvature of 45 ° to 90 °, and the cross-sectional shape is concavely rising from the flat part 13, and the part convexly descending from the upper part 15 (15). And a single corrugation 11 formed in a shape having an end portion 21 in the longitudinal direction, a straight portion 18 protruding crosswise in a 45 ° direction, and a round formed at the end of the straight portion. The rounded convex part 17 and the rounded concave part 16 which the said linear part meet each other are comprised, The convex part 17, the concave part 16, and the straight part 18 are the cross-shaped corrugation center part 19 And a concave portion 14 and a convex portion 15 descending from an upper portion of the flat portion 13 and have a curvature on the corner wall and are rounded to form the ends of the two unitary corrugations 11. Bent formed at a position between 21 Shaped corner koreo navigation structure of the low temperature fluid, characterized in that the membrane consists of koreo navigation 12, a flat portion 13, there is no koreo ligated. According to claim 1, wherein a straight portion is formed between the concave portion 14 and the convexly descending portion 15 from the flat portion 13 of the unitary corrugation 11, cross-shaped corrugation (12) ), The convex portion 17, the concave portion 16 and the straight portion 18 are concave up from the cross-shaped corrugation center portion 19 and the flat portion 14 (14 ') and the portion convexly descending from the top. Corner corrugation structure of a cryogenic liquid storage tank membrane, characterized in that a straight portion is formed between (15 '). The portion 15 of claim 1, wherein the central portion 19 of the cross-shaped corrugation 12 does not enter concave, but may include a portion 14 that rises concave from the flat portion 13 and a portion that rises convexly upward. The corner corrugation structure of the cold liquid storage tank membrane, which is composed of the cross-shaped corrugation center portion 19 in the c) as the protrusion portion 19 '. 4. The corner corrugation structure of a cryogenic liquid storage tank membrane according to claim 3, wherein the low temperature liquid storage tank membrane has a cross-shaped structure without the protrusion (19 ').

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