KR101682073B1 - Liquefied Natural Gas Storage Tank - Google Patents

Abstract

There is provided a liquefied natural gas leak detection system installed in a liquefied natural gas storage tank.
Wherein the storage tank includes an inner wall surface having a first sealing wall, a second sealing wall and a heat insulating layer, the second sealing wall including a stepped portion that is stepped toward the heat insulating layer at a distance from the first sealing wall, The liquefied natural gas leakage detection system includes a detection device provided at a stepped portion of the second sealing wall.

Description

Liquefied Natural Gas Storage Tank [0002]

The present invention relates to a liquefied natural gas storage tank for detecting the leakage of liquefied natural gas by measuring the temperature change by taking advantage of the fact that the liquefied natural gas is at a cryogenic temperature.

With growing interest in eco-friendly businesses globally, the demand for clean fuels that can replace existing energy sources such as petroleum and coal is increasing. In addition, efforts to reduce dependence on oil have been steadily taking place as a part of government policy through continuous oil price increases and two oil crises of the 1970s. In this situation, natural gas is expected to be a major energy source with cleanliness, stability and convenience. Unlike in the US and Europe, where natural gas is directly supplied through pipelines, Korea is supplying liquefied natural gas (LNG), which is liquefied at extremely low temperatures, to consumers. Therefore, the demand for domestic natural gas is increasing with the demand for storage tanks for storing liquefied natural gas.

Liquefied natural gas is obtained by cooling natural gas to a cryogenic temperature of approximately -163 ° C, and its volume is considerably reduced compared to when it is in a gaseous state, making it well suited for long-distance transport through the sea. The liquefied natural gas carrier is intended for unloading liquefied natural gas on land by transporting liquefied natural gas to the sea, including a cryogenic storage tank for liquefied natural gas.

The storage tanks can be classified as independent tanks and membrane types depending on whether the load of the cargo directly acts on the insulation. Membrane-type storage tanks are divided into GTT NO 96 type and Mark III type. Independent tank type storage tanks are divided into MOSS type and IHI-SPB type. GTT NO 96 and GTT Mark III were formerly called GT type and TGZ type. In 1995, the names of GT (GT) and Technigaz (TGZ) were changed to GTT (Gaztransport & Technigaz) 96 type, and the TGZ type is replaced with the GTT Mark III type.

Storage tanks are classified into Single Containment Tank, Double Containment Tank and Full Containment Tank depending on the protection method in case of an accident.

A single protective tank is a tank designed and constructed to meet the requirements of low-temperature ductility only when the tank is in direct contact with the cold liquid. Dike is used to prevent secondary damage due to leakage of cryogenic liquid from the tank. need.

The double protection tank is a type of tank designed and built so that the inner tank and outer tank satisfy the conditions of low temperature ductility. The outer tank is designed and constructed so as to store the liquid leaked due to the breakdown of the inner tank, but does not consider the leakage prevention function of the vaporized gas.

A fully protected tank shall satisfy the low temperature ductility condition both in the inner tank and the outer tank as in the double protection tank. The outer tank is designed and constructed so as to not only store the leaked liquid but also to prevent gas leakage when the inner tank is broken.

Until the 1970s, a single protective tanks built primarily were called first generation tanks, and double protected tanks built after the 1970s and fully protected tanks were classified as second generation tanks.

KOGAS has established a cooperative system with Whessoe in the UK and has completed the design of a fully protective storage tank of 14,000 ㎘ grade 9% nickel (Ni) in 2001, leading the domestic storage tank design market. In addition, Korea Gas Corporation and Korea Gas Technology Corporation have independently developed membrane type storage tanks.

Unlike typical infrastructure facilities such as bridges, buildings, and dams, storage tanks must consider the design and behavior of cryogenic liquids safely to safely store cryogenic natural gas. In case of leakage of liquefied natural gas, the temperature of the specific part of the outer tank is lowered to -162 ° C. Therefore, it is essential to analyze the leakage of liquefied natural gas in consideration of such sudden temperature change and fluid pressure.

When liquefied natural gas leaks due to internal damage, the inner surface of the outer tank is directly exposed to the liquefied natural gas, and the outer tank receives a large temperature load due to rapid temperature changes. In addition, liquefied natural gas leaking from the inner tank gradually accumulates and acts as a load on the inner wall of the outer tank.

Therefore, rapid detection of leakage of the storage tank is very important to prevent explosion and subsequent breakage of the storage tank.

As a technique to prepare for the leakage of conventional liquefied natural gas, there is a leaking liquid collecting apparatus of a stand-alone storage tank of the patent document 10-2010-0123982 and a leaking position tracking system and method of the LNG storage tank of the patent document 10-2010-0115544 .

The leakage liquid collecting device of the independent type storage tank of the patent document 10-2010-0123982 is a technique for collecting leaked liquefied natural gas instead of detecting leakage of the liquefied natural gas, The system and method for detecting the location of the leak tanks of the storage tanks is a technique for finding the position where the liquefied natural gas is leaked. In order to improve the safety of the storage tanks, research and development of techniques for more effectively detecting the leakage of liquefied natural gas Is continuously required.

In the case of a generally used liquefied natural gas storage tank, since a heat insulating layer is provided between the first sealing wall and the second sealing wall, in the state where the liquefied natural gas is not leaked, the first sealing wall There is a difference in temperature of the second sealing wall having the heat insulating layer between the temperature of the first sealing wall and the first sealing wall.

Therefore, when the liquefied natural gas leaks and flows toward the second sealing wall, the temperature around the second sealing wall is lowered, so that it is possible to detect the leakage of the liquefied natural gas by measuring the temperature around the second sealing wall.

However, in the case of the storage tank of the present invention, since there is no insulating layer between the first sealing wall and the second sealing wall, the temperature of the first sealing wall contacting the liquefied natural gas even when the liquefied natural gas does not leak, The temperature of the second sealing wall, which is installed in close proximity to the first sealing wall, is similar to the temperature of the liquefied natural gas. Therefore, even if the liquefied natural gas leaks and flows toward the second sealing wall, there is a problem that it is not possible to clearly detect the leakage of the liquefied natural gas by simply measuring the temperature around the second sealing wall.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a liquefied natural gas storage tank including a second sealing wall having a step portion at a distance from the first sealing wall.

According to an aspect of the present invention, there is provided a liquefied natural gas leakage detection system installed in a liquefied natural gas storage tank, wherein the storage tank includes an inner wall surface having a first sealing wall, a second sealing wall, And the second sealing wall includes a step formed so as to be stepped toward the heat insulating layer at a distance from the first sealing wall, wherein the liquefied natural gas leakage detecting system comprises: A liquefied natural gas leak detection system is provided.

The detection device may be installed at the bottom of the storage tank.

Wherein the detection device comprises: a collection space in which leaked liquefied natural gas is collected; An induction passage for guiding the leaked liquefied natural gas to the collection space; And a sensor for measuring the temperature of the collection space.

The collecting space may be formed below the induction passage.

The liquefied natural gas leakage detection system may further include a sensor cable connected to the sensor.

A plurality of the sensor cables may be fixed together by a single fixing member.

The detecting device may include a plurality of the sensors.

A plurality of the detecting devices may be provided.

According to another aspect of the present invention, there is provided a method for detecting a liquefied natural gas leak in a liquefied natural gas storage tank, the method comprising: installing a first sealing wall, a second sealing wall and a heat insulating layer in the storage tank; Forming a step on the second sealing wall so as to be stepped toward the heat insulating layer at a distance from the first sealing wall; Installing an induction passageway, a collecting space and a sensor on the stepped portion; Collecting the leaked liquefied natural gas into the collection space through the induction passage; Sensing a liquefied natural gas collected in the collection space by a sensor; And transmitting the signal received by the sensor through a sensor cable.

According to another aspect of the present invention, there is provided an apparatus for detecting a liquefied natural gas leak in a liquefied natural gas storage tank, comprising: A liquefied natural gas leakage detection device is provided.

The liquefied natural gas leak detection system of the present invention includes the second sealing wall having the stepped portion at a distance from the first sealing wall so that the temperature difference between the leaked natural gas and the leaked natural gas can be increased , The leakage of liquefied natural gas can be clearly detected.

Further, the liquefied natural gas leakage detection system of the present invention comprises: an induction passage for guiding liquefied natural gas into a collection space; Collection space for liquefied natural gas; And a sensor for measuring the temperature of the collection space. Therefore, it is possible to efficiently collect liquefied natural gas by collecting the leaked liquefied natural gas into the collecting space.

1 is a perspective view schematically showing a liquefied natural gas detection system according to a preferred embodiment of the present invention.
2 is a side view schematically showing a detection device for a liquefied natural gas detection system according to a preferred embodiment of the present invention.
3 is a plan view schematically showing a detection device for a liquefied natural gas detection system according to a preferred embodiment of the present invention.
4 is a cross-sectional view schematically showing part A of Fig.
5 is a cross-sectional view schematically showing a portion B in Fig.
6 is a cross-sectional view schematically showing a portion C in Fig.
7 is a cross-sectional view schematically showing a portion D in Fig.
8 is a side view schematically showing part E of Fig.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The following examples are intended to illustrate the present invention and should not be construed as limiting the scope of the present invention.

1 is a perspective view schematically showing a liquefied natural gas detection system according to a preferred embodiment of the present invention.

Referring to Fig. 1, the liquefied natural gas detecting system of the present embodiment includes a detecting device 3 for detecting leaked liquefied natural gas; And a sensor cable (4) connected to the detecting device (3).

The liquefied natural gas detecting system of the present embodiment includes a total of ten detecting devices 3, but the number of detecting devices 3 may be changed as necessary And one sensor cable 4 is connected to one detection device 3. [

FIG. 2 is a side view schematically showing a detection device 3 of a liquefied natural gas detection system according to a preferred embodiment of the present invention, and FIG. 3 is a side view schematically showing the detection device 3 of a liquefied natural gas detection system according to a preferred embodiment of the present invention 3). ≪ / RTI >

1 and 2, when the detecting device 3 and the sensor cable 4 are installed on the wall surface or the bottom surface of the storage tank 2, the liquefied natural gas is stored in the storage tank 2, There is a risk that the sensing device 3 and the sensor cable 4 are damaged due to the flow of the liquefied natural gas caused by the movement of the hull 1 and the sensor cable 3 and the sensor cable 4 are exposed to extremely low temperatures. Therefore, the detecting device 3 and the sensor cable 4 of this embodiment are installed between the heat insulating layer 2c of the storage tank 2 and the hull 1.

A plurality of detecting devices 3 of the present embodiment are provided between the heat insulating layer 2c at the bottom of the storage tank 2 and the hull 1. Liquefied natural gas is heavier than air, so that the leaked liquefied natural gas is collected toward the bottom of the storage tank (2). Therefore, it is preferable that the detection device 3 is installed on the bottom side of the storage tank 2, but the installation position of the detection device 3 is not limited to the bottom side of the storage tank 2.

Referring to FIGS. 2 and 3, the detecting device 3 of the present embodiment is installed so that leaked liquefied natural gas can be gathered in one place and the sensor 3d can efficiently detect the leakage of liquefied natural gas. A collecting space (3c) for collecting leaked liquefied natural gas; An induction passage 3b for guiding the leaked liquefied natural gas to the collection space 3c; And a sensor 3d for measuring the temperature of the collection space 3c.

The inner wall of the storage tank 2 of the present embodiment includes a first sealing wall 2a, a second sealing wall 2b and a heat insulating layer 2c in the direction from the inside to the outside, and the first sealing wall 2a And the second sealing wall 2b, a sealing wall space 3a is formed. When the liquefied natural gas leaks, the leaked liquefied natural gas flows through the space 3a between the sealing walls.

The second sealing wall 2b of the present embodiment includes a step portion formed so as to be stepped toward the heat insulating layer 2c at a distance from the first sealing wall 2a and the detecting device 3 of this embodiment has the liquefied natural gas And is installed at the step of the second sealing wall 2b to maintain a temperature higher than that of the liquefied natural gas when it is not leaked.

The collecting space 3c included in the detecting device 3 of the present embodiment is connected to one end of the induction passage 3b so that the leaked liquefied natural gas is guided and collected by the induction passage 3b It is an empty space.

The collecting space 3c of this embodiment is formed immediately below the step of the second sealing wall 2b so that the collecting space 3c forming position is not limited to just below the step of the second sealing wall 2b , It is preferable that the first sealing wall 2a is formed on the side of the heat insulating layer 2c so as to be sufficiently different in temperature from the liquefied natural gas.

One side of the collection space 3c is connected to the sensor 3d so that the temperature of the collection space 3c can be measured by the sensor 3d. When the liquefied natural gas does not leak, the collecting space 3c is separated from the first sealing wall 2a and therefore maintains a temperature higher than that of the liquefied natural gas. When the liquefied natural gas is leaked, The temperature of the collecting space 3c becomes approximately equal to the temperature of the liquefied natural gas because it is guided by the collecting space 3c and collected in the collecting space 3c.

That is, when the temperature of the collection space 3c measured by the sensor 3d is lowered to be substantially equal to that of the liquefied natural gas, it can be determined that the liquefied natural gas has leaked.

The liquefied natural gas flows downward by gravity, so that the collection space 3c is preferably formed below the space 3a between the sealing walls and the guide passage 3b.

The induction passage 3b included in the detecting device 3 of the present embodiment is a passage for connecting the space 3a between the sealing wall and the collecting space 3c and the liquefied natural gas collected in the space 3a between the sealing walls And leads to the collection space 3c so that the leaked liquefied natural gas can be collected in the collection space 3c. One end of the induction passage 3b is connected to the collection space 3c and the other end of the induction passage 3b is connected to the space 3a between the seal walls.

The sensor 3d included in the detection device 3 of the present embodiment is connected to the collection space 3c on one side and to the sensor cable 4 on the other side so that the temperature of the collection space 3c can be measured. In addition, one detecting device 3 includes a plurality of sensors 3d to increase the reliability of the judgment as to whether or not there is leakage.

When the liquefied natural gas leaks from the storage tank 2, the liquefied natural gas is collected into the collecting space 3c through the sealing wall space 3a and the induction passage 3b, The temperature of the liquefied natural gas collected in the storage tank 3c can be measured and the detection device 3 can confirm whether or not the liquefied natural gas leaks in the storage tank 2.

FIG. 4 is a cross-sectional view schematically showing parts A1 to A4 of FIG. 1, FIG. 5 is a cross-sectional view schematically showing part B of FIG. 1, FIG. 6 is a cross- FIG. 7 is a cross-sectional view schematically showing part D of FIG. 1, and FIG. 8 is a side view schematically showing part E of FIG.

1, 2 and 8, one end of the sensor cable 4 of the present embodiment is connected to the sensor 3d included in the detecting device 3, and the other end is connected to the outside of the storage tank 2 And connected to a sensor control unit not shown.

The sensor cable 4 is provided to transmit a signal detected by the sensor 3d included in the detection device 3 to a sensor control unit provided outside the storage tank 2. [

1 and 4 to 7, the sensor cable 4 connected to each of the detecting devices 3 is connected to the bottom of the storage tank 2 together with one fixing member 6a at the portions A1 to A4, And is fixed between the heat insulating layer 2c and the hull 1 at a portion thereof.

The two sensor cables 4 fixed by one fixing member 6a in each of the A1 and A2 portions meet each other and are joined together by one fixing member 6b in the portion B to form a heat insulating layer (2c) and the hull (1).

The four sensor cables 4 fixed by one fixing member 6b in the portion B are connected to two sensor cables 4 connected to the detecting device 3 at the center of the bottom of the storage tank 2, And is fixed between the insulating layer 2c of the bottom portion of the storage tank 2 and the hull 1 together by a single fixing member 6c.

Six sensor cables 4 fixed by one fixing member 6c in the portion C meet the sensor cable 4 in the portions A3 and A4.

1 and 8, all the sensor cables 4 installed on the bottom surface of the storage tank 2 ride together between the heat insulating layer 2c of the wall portion of the storage tank 2 and the hull 1, The ten sensor cables 4 are fixed together by one fixing member 6d.

The sensor cables 4 ascending on the wall surface of the storage tank 2 are connected to a sensor control unit provided outside the storage tank 2 and transmit signals sensed by the sensor 3d to the sensor control unit.

The liquefied natural gas leakage detection system of the present invention can increase the temperature difference between when the liquefied natural gas is leaked and when the liquefied natural gas is not leaked. Therefore, it is possible to clearly detect the leak of the liquefied natural gas, Can be collected in the collecting space (3c), so that it is possible to detect the leakage of the liquefied natural gas efficiently.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention. It is.

1: Hull 2: Storage tank
2a: first sealing wall 2b: second sealing wall
2c: Insulating layer 3: Detecting device
3a: space between sealing walls 3b: guide passage
3c: collection space 3d: sensor
4: Sensor cable 6a, 6b, 6c, 6d: Fixing member

Claims (10)

A first sealing wall;
A second sealing wall;
A heat insulating layer provided between the second sealing wall and the hull; And
And a detecting device provided at a step of the second sealing wall,
The detecting device includes:
Collection space where leaked liquefied natural gas collects;
An induction passage for guiding the leaked liquefied natural gas to the collection space; And
And a sensor for measuring the temperature of the collection space,
Wherein the stepped portion is formed toward the heat insulating layer such that the collecting space is spaced from the first sealing wall,
When the liquefied natural gas does not leak, the temperature of the collecting space is higher than the temperature of the first sealing wall by the step portion,
And a heat insulating layer is not provided between the first sealing wall and the second sealing wall. The method according to claim 1,
Wherein the detection device is installed on the bottom side of the liquefied natural gas storage tank. delete The method of claim 2,
Wherein the collection space is formed below the guide passage. The method according to claim 1, 2 or 4,
Wherein the sensor is connected to a sensor cable. The method of claim 5,
Wherein the plurality of sensor cables are fixed together by a single fixing member. The method according to claim 1, 2 or 4,
Wherein said sensing device comprises a plurality of said sensors. The method according to claim 1, 2 or 4,
The liquefied natural gas storage tank is provided with a plurality of detection devices. delete delete

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