KR20210083651A - Pump Tower of Liquefied Gas Storage Tank - Google Patents

Abstract

A pump tower of a liquefied gas storage tank is disclosed. The pump tower of the liquefied gas storage tank according to the present invention comprises: a housing for fixing a pump tower coupled to the lower end of a pipe serving as a main structural member for a load in the pump tower mounted on a liquefied gas storage tank; and a holder for fixing the pump installed on one side of the housing for fixing the pump tower and mounted with a cargo pump provided in the pump tower. Before the mounting of the pump tower to the liquefied gas storage tank is made, the fixing of the housing for fixing the pump tower to the lower end of the pipe and the mounting of the cargo pump to the holder for fixing the pump are preceded.

Description

Pump Tower of Liquefied Gas Storage Tank

The present invention relates to a pump tower for a liquefied gas storage tank, and more particularly, to a pump tower for a liquefied gas storage tank designed to be suitable for a medium/small liquefied gas storage tank with a simpler and lighter structure than a conventional large pump tower. will be.

Liquefied natural gas (hereinafter 'LNG') is obtained by cooling natural gas to a cryogenic temperature (approximately -163℃). It is very suitable for long-distance transport.

Vessels that load and unload LNG to destinations on land by operating the sea with LNG, such as LNGC (LNG Carrier), or ships propelled using LNG as fuel, such as LFS (LNG Fueled Ship), can withstand the cryogenic temperature of LNG. A storage tank is installed.

In addition, in such an LNG storage tank, a pump tower, which is a pipe structure, is installed therein for loading and unloading of LNG. The pump tower supports various types of piping and an LNG cargo pump, and is also used as a pipe for transporting LNG through a pipe.

1 is an internal perspective view schematically showing the structure of an LNG storage tank including a conventional pump tower, FIG. 2 is a perspective view showing the overall structure of the conventional pump tower, and FIG. 3 is a plan view of the conventional pump tower. And Figure 4 is a perspective view of a base support installed to support the conventional pump tower, Figure 5 is a view showing a structure in which the conventional pump tower is fixed to the base support.

Referring to FIG. 1 , in general, the upper part of the pump tower 10 is fixed to a liquid dome of the ceiling of an LNG storage tank. And the lower part of the pump tower 10 is supported by a base support installed on the bottom of the LNG storage tank, and the structure thereof can be confirmed in FIG. 5 .

The pump tower 10 is usually installed close to the stern side bulkhead of the LNG storage tank. This is to enable more efficient suction of LNG in the lower part of the storage tank under trim conditions.

Looking at the structure of the conventional pump tower in more detail with reference to FIGS. 2 and 3 , the pump tower 10 is typically two discharge pipes (discharge pipe, 11) and one filling pipe (filling pipe, 12). Together with, it is composed of an emergency column (emergency column, 13) that can be used in an emergency when the discharge pipe does not operate normally.

The conventional pump tower 10 is composed of three main pipes and support pipes 14 of a truss work connecting them to have a stable structure. More specifically, a pair of discharge pipes 11 and an emergency column 13 constitute the main pipe to serve as a main structural member for supporting the load acting on the pump tower 10, and the discharge pipe ( 11) and a plurality of support pipes 14 supporting the emergency column 13 support the stress generated in the process of discharging LNG.

On the other hand, since the filling pipe 12 is exposed to an environment where the temperature difference between the inside and outside of the pipe is extreme when LNG is shipped in a state where the LNG storage tank is empty, it is spaced apart from the truss structure in consideration of the heat shrinkage of the pipe. Typically, the filling pipe 12 is spaced apart and disposed in the form of a sleeve on the side of the emergency column 13 .

That is, the filling pipe 12 has a structure separate from the main pipes 11 and 13 so that stress due to heat shrinkage that may occur when LNG is injected is not transmitted to the structure, and is separated from the support pipes 14 of the truss structure. are also not connected to each other.

The discharge pipe 11 is provided as a movement passage for LNG when the LNG stored in the LNG storage tank is unloaded overboard. A cargo pump (CP) is installed in the lower portion of the discharge pipe 11 to discharge the LNG stored in the LNG storage tank to the outside. Although only one cargo pump (CP) is shown in the drawings for convenience of description, the cargo pump is provided correspondingly to the lower portion of the discharge pipe 11 on the rear side that is covered by the emergency column 13 .

The filling pipe 12 is connected to an external loading device and serves to introduce LNG into the LNG storage tank.

The emergency column 13 is installed to replace the discharge pipe 11 when the cargo pump CP fails. The emergency column 13 provides a place where an emergency pump is installed, and when the cargo pump CP fails, the emergency pump operates to discharge the LNG stored in the LNG storage tank to the outside.

The conventional pump tower 10 as described above, since it is required to install the filling pipe 12 to be spaced apart from the main pipes 11 and 13, which are the main structural members, the structure is complicated and the pump tower 10 In addition to causing an increase in the load of the equipment, a lot of economic cost is borne in the construction of the facility. In addition, a structure in which the filling pipe 12 is separately disposed outside the emergency column 13 is inefficient in terms of utilization of the internal space of the LNG storage tank.

The conventional pump tower 10 is supported by a base support 20 whose lower part is installed on the bottom of the LNG storage tank.

Referring to FIG. 4 , the base support 20 installed to support the conventional pump tower 10 is a lower support 21 fixed to the inner wall of the hull H by welding, and an upper portion of the lower support 21 . It includes an upper support 22 coupled to, and a socket portion 23 coupled to both sides of the upper support 22 .

The upper support 22 is provided in a cylindrical shape having the same diameter with respect to the entire height so as to uniformly transmit the applied load in the downward direction. And the lower support 21 is provided in the shape of a cone (corn) gradually decreasing in diameter from the lower part to the upper part so as to stably distribute the load transmitted from the upper part.

And referring to FIG. 5 , a base plate 15 is provided at the lower end of the pump tower 10 to support the base support 20 . A discharge pipe 11 , an emergency column 13 , and a cargo pump CP are fixed to the base plate 15 , and a fastening part 16 is provided on the lower side for fastening with the base support 20 .

The fastening part 16 is fastened in such a way that it is inserted into the socket part 23 of the above-described base support 20 . That is, the conventional pump tower 10 is fixed and supported on the base support 20 by the fastening part 16 provided at the lower end being fastened to the socket part 23 .

Republic of Korea Patent Publication No. 10-0695963 (2007.03.09) Republic of Korea Patent Publication No. 10-2015-0116257 (2015.10.15)

As described above, in general, a liquid dome is provided as an opening for mounting the pump tower on the upper portion of the LNG storage tank. The liquid dome is a structure provided by forming an opening in the upper part of the storage tank for installation of pipes and equipment related to the processing of LNG in a liquefied state.

In addition, a gas dome is further provided in the upper portion of the LNG storage tank separately from the liquid dome. The gas dome is a structure provided by forming an opening in the upper part of the storage tank for the installation of piping and equipment related to the treatment of boil-off gas (BOG) in which LNG is vaporized. The gas dome suppresses the evaporation of BOG. a spraying pipe that injects LNG into the storage tank, a venting pipe for discharging BOG generated inside the storage tank or supplying it as fuel for the engine, and nitrogen (nitrogen) as an inert gas in the storage tank. N ₂ ) A purging pipe for supplying gas, etc. is provided.

The spray pipe provided in the gas dome is also used to suppress BOG generated inside the LNG storage tank during the operation of the ship, but it is cooled down to cool the inside of the storage tank before shipping LNG to the LNG storage tank. It is also used for performing (cool-down) tasks.

Meanwhile, in the existing LNG storage tank, the liquid dome and the gas dome are separated from each other and installed separately. The reason why the liquid dome and the gas dome had to be installed separately is as follows.

Basically, the liquid dome should be placed on the stern side in order to more efficiently suck the LNG in the lower part of the storage tank under trim conditions, whereas in the case of the gas dome, it has the most effect on the LNG in the liquefied state with respect to trim and 6 degree of freedom motion. It should be placed in the center of the storage tank, which is less exposed to

In addition, since the liquid dome makes it difficult for large equipment or insulation materials to enter or exit due to the pump tower structure installed at the bottom, the LNG storage tank was designed so that equipment for maintenance or insulation materials can be moved through the gas dome. That is, for the convenience of maintenance, the liquid dome and the gas dome had to be designed separately from each other.

As described above, the existing design in which the liquid dome and the gas dome are separately installed at the stern side and the center of the LNG storage tank may be a suitable design for a large LNG storage tank provided in an LNGC, but it is not suitable for a medium/small size LNG storage tank. This is a very inefficient design.

However, in the prior art, by imitating the existing method to small and medium-sized LNG storage tanks as it is, there was a problem in that productivity was lowered due to a complicated structure, and thermal insulation performance of the storage tank was lowered by heat flowing into the two dome structures.

In addition, it is not easy to mount a conventional large pump tower structure suitable for a large LNG storage tank in a medium/small LNG storage tank, and the sloshing load in a medium/small LNG storage tank is higher than that in a large LNG storage tank. Since this occurs less, manufacturing the base support in a complex shape as in the conventional method (see FIG. 4 ) is rather excessively overdesigned, which further reduces productivity.

Accordingly, an object of the present invention is to provide a thermal insulation system optimized for a liquefied gas storage tank manufactured in a small/medium size, and more specifically, a liquid dome and a gas dome, which have been separately provided in the past, are converted into a single dome structure. By integrating, it is intended to improve productivity and reduce cost by simplifying the complex structure around the dome as well as improving the insulation performance compared to the existing one.

In addition, as the present invention simplifies the structure of the liquefied gas storage tank as described above, the present invention proposes a pump tower having a simpler and lighter structure than the conventional large pump tower, and the fixed and supporting structure is also newly developed to suit the proposed pump tower. By improving, it is a technical task to provide the most optimized insulation system for a medium/small liquefied gas storage tank including an integrated dome structure.

According to an aspect of the present invention for achieving the above object, the pump tower fixing housing coupled to the lower end of the pipe serving as a main structural member for the load in the pump tower mounted on the liquefied gas storage tank; And it is installed on one side of the housing for fixing the pump tower and includes a cradle for fixing the pump on which the cargo pump provided in the pump tower is mounted, before the mounting of the pump tower in the liquefied gas storage tank is made, the A pump tower of a liquefied gas storage tank may be provided, characterized in that the fixing of the housing for fixing the pump tower to the lower end of the pipe and the mounting of the cargo pump to the cradle for fixing the pump are preceded.

As the cradle for fixing the pump is integrally coupled to the side of the pump tower, a separate structure for fixing the pump may not be installed on the base support installed at the bottom of the liquefied gas storage tank to support the pump tower. have.

The uppermost surface of the base support may be flush with the primary membrane installed in the liquefied gas storage tank, and the inlet of the cargo pump may be installed close to the bottom surface of the liquefied gas storage tank.

The pump tower of the liquefied gas storage tank according to an aspect of the present invention may further include a fixing device installed on the base support and supporting the four sides of the housing for fixing the pump tower in surface contact.

The cradle for fixing the pump may be formed to protrude from both edges while leaving a central portion on one side of the housing for fixing the pump tower to secure an installation space of the fixing device.

The remaining pipes disposed in the periphery of the pipe may be slidably supported on the pipe.

The remaining pipes may be supported by a support frame installed on the outer circumferential surface of the pipe, and may be inserted through an insertion hole formed in the support frame to allow sliding flow in the vertical direction.

A sliding pad for preventing friction during sliding may be attached to the inner circumferential surface of the insertion hole.

The sliding pad may be made of a high-density polyethylene (HDPE) material.

According to the present invention, by integrating the liquid dome and the gas dome, which were previously installed separately, into one dome, the complex structure around the dome is simplified to improve productivity, and heat flowing into the storage tank is minimized to minimize the liquefied gas There is an effect of improving the thermal insulation performance of the storage tank.

In addition, according to the present invention, as the pump tower mounted on the liquefied gas storage tank is designed to have a simple and light structure compared to the prior art, it is easy to manufacture the pump tower to reduce costs, and the entire liquefied gas storage tank Efficient operation of the vessel is possible by reducing the weight.

In addition, according to the present invention in which the filling pipe and the spraying pipe are provided in a double piping structure, the space for installing the spraying pipe is minimized, so that it is possible to reduce the size of the dome structure, and thus heat penetration through the dome structure It has the effect of improving the thermal insulation performance by reducing the amount.

In addition, according to the present invention, an improved pump tower fixing/supporting structure is provided so that the pump tower can be easily and conveniently mounted in the liquefied gas storage tank, thereby increasing the convenience for welding and reducing the on-site construction time, resulting in productivity This improved effect can be achieved.

On the other hand, even if it is an effect not explicitly mentioned herein, it is added that the effects described in the following specification and their potential effects expected by the technical features of the present invention are treated as if they were described in the specification.

1 is an internal perspective view schematically showing the structure of an LNG storage tank including a conventional pump tower.
2 is a perspective view showing the overall structure of a conventional pump tower.
3 is a plan view of a conventional pump tower.
4 is a perspective view of a base support installed to support the conventional pump tower.
5 is a view showing a structure in which the conventional pump tower is fixed to the base support.
6 is a front view showing the overall structure of the pump tower according to the present invention.
7 is a perspective view showing a structure in which various pipes are connected to the dome housing which is the upper structure of the pump tower according to the present invention.
8 is an enlarged perspective view of the connection part of the filling pipe in the pump tower according to the present invention.
9 is a cross-sectional view showing the upper internal structure of the pump tower according to the present invention.
10 is a perspective view showing the structure of the lower end of the spray pipe disposed in the pump tower according to the present invention.
11 is a view showing the lower structure of the pump tower according to the present invention, (a) is a front view, (b) is a side view.
12 is a plan view showing the lower structure of the pump tower according to the present invention.
13 is a perspective view showing a structure in which the pump tower according to the present invention is fixed on the base support.
14 is a perspective view showing the coupling relationship of the fixing device installed on the base support to fix the pump tower according to the present invention.
15 is a front view showing a structure in which the pump tower according to the present invention is fixed on the base support.
16 is a plan view showing a structure in which the pump tower according to the present invention is fixed on the base support.

In order to fully understand the present invention, the operational advantages of the present invention, and the objects achieved by the practice 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.

The present invention can be applied to all ships equipped with a liquefied gas storage tank for handling liquefied gas as transport, including ships that consume liquefied gas as propulsion fuel, such as LFS. In the present invention, a ship is a concept including all offshore structures floating in the sea, including a ship having a self-propelling capability.

In particular, the present invention is designed to be suitable for a medium/small liquefied gas storage tank, and can be preferably applied to a ship equipped with a small liquefied gas storage tank. Here, the medium/small liquefied gas storage tank may mean a low-capacity liquefied gas storage tank, such as a fuel tank used for a liquefied gas fuel propulsion ship, a storage tank for coastal transportation, or a storage tank used anchored in a port, specifically may mean a storage tank with a loading capacity of 50,000 m ³ or less, more specifically 25,000 m ^{3 or less.}

And in the present invention, liquefied gas is low temperature such as LNG, which is the most representative liquefied gas, LEG (Liquefied Ethane Gas), LPG (Liquefied Petroleum Gas), Liquefied Ethylene Gas, Liquefied Propylene Gas, etc. It is a concept that includes all kinds of liquefied gas that can be stored and transported by liquefying it.

Hereinafter, the present invention will be described in detail by describing preferred embodiments of the present invention with reference to the accompanying drawings. Like reference numerals in each figure indicate like elements.

6 is a front view showing the overall structure of the pump tower according to the present invention, FIG. 7 is a perspective view showing a structure in which various pipes are connected to the dome housing which is the upper structure of the pump tower according to the present invention, and FIG. An enlarged perspective view of the connection part of the filling pipe in the pump tower, FIG. 9 is a cross-sectional view showing the upper internal structure of the pump tower according to the present invention, and FIG. 10 is the lower end structure of the spraying pipe disposed in the pump tower according to the present invention A perspective view is shown.

And Figure 11 is a view showing the lower structure of the pump tower according to the present invention, (a) is a front view, (b) is a side view, Figure 12 is a plan view showing the lower structure of the pump tower according to the present invention, Figure 13 is a perspective view showing the structure in which the pump tower according to the present invention is fixed on the base support, Figure 14 is a perspective view showing the coupling relationship of the fixing device installed on the base support to fix the pump tower according to the present invention, Figure 15 is A front view showing the structure in which the pump tower according to the present invention is fixed on the base support, FIG. 16 is a plan view showing the structure in which the pump tower according to the present invention is fixed on the base support.

6, the liquefied gas storage tank according to the present invention, an integrated dome provided in the form of an opening on the upper portion of the storage tank, a pump tower 100 installed inside the storage tank, and a pump tower ( The lower end of the 100) includes a base support 200 that is fixed and supported.

The integrated dome is a configuration in which the existing liquid dome and gas dome are integrated into one, and piping and equipment related to handling of liquefied gas in a liquefied state, and piping and equipment related to handling of boil-off gas generated by evaporation of liquefied gas are installed. . Such various piping and equipment may be provided in the pump tower 100 , and the integrated dome provides a place where the pump tower 100 is installed.

The integrated dome is a structure provided by forming an opening so as to penetrate the ceiling of the liquefied gas storage tank, and in the drawings below, the integrated dome is formed by the opening having a circular cross section, but the present invention is not limited thereto. It may be provided as an opening having a

The integrated dome can be used as a passage through which various pipes and equipment enter and exit the liquefied gas storage tank. However, since the access of equipment through the integrated dome becomes impossible after the installation of the pump tower 100, the present invention provides a separate manhole in the upper part of the liquefied gas storage tank so that equipment for maintenance or an operator can enter and exit. city) may be additionally provided.

As described above, the pump tower 100 is a structure in which piping and equipment related to handling of liquefied gas and boil-off gas are installed, and is mounted using an opening forming an integrated dome and the upper part is fixed to the integrated dome side. And the lower part of the pump tower 100 is supported by the base support 200 installed on the bottom of the liquefied gas storage tank.

The pump tower 100 of the present invention includes a dome housing 110 mounted on an integrated dome in the form of an opening provided on an upper portion of a liquefied gas storage tank, and a filling pipe 120 for injecting liquefied gas into the liquefied gas storage tank. And, it includes a pair of discharge pipes 130 for discharging the liquefied gas inside the liquefied gas storage tank to the outside.

The dome housing 110 is provided in a cylindrical shape with a hollow inside and can be mounted in close contact with the inner circumferential surface of the integrated dome, and the lower part is opened to provide a space for various pipes to extend into the liquefied gas storage tank, and the upper part is closed. Seal the integrated dome.

The lower end of the dome housing 110 is installed in close contact with the inner circumferential surface of the integrated dome so as to protrude from the upper part of the liquefied gas storage tank, and various pipes are connected to the upper part of the liquefied gas storage tank to penetrate the tank. extended inward. The dome housing 110 serves to secure various pipes accommodated inside and surround them to protect them.

The dome housing 110 constitutes an airtight seal by fixing the lower peripheral surface to the ceiling outer wall (inner hull) of the liquefied gas storage tank by welding, thereby preventing leakage of liquefied gas inside the liquefied gas storage tank. can

In this case, the lower end welded to the outer wall of the liquefied gas storage tank in the dome housing 110 may be manufactured as a sleeve type having an increased thickness for leveling operation. When the lower end of the dome housing 110 is provided in a sleeve type as described above, it is possible to adjust the welding portion of the dome housing 110 up and down when the pump tower 100 is mounted in the liquefied gas storage tank, so the pump tower 100 There is an advantage that no additional work is required to match the gap between the lower end of the pump tower 100 and the upper part of the base support 200 when fixing the on the base support 200 .

The filling pipe 120 is a pipe connected to an external loading device to introduce liquefied gas into the liquefied gas storage tank.

In the present invention, the filling pipe 120 is installed to pass through the upper center of the dome housing 110 and is disposed in the central portion of the pump tower 100 . And the filling pipe 120 serves as a main support (main support) for the load acting on the pump tower 100 by being directly fixed to the lower end of the base support 200 to be described later. That is, unlike the conventional (refer to FIGS. 2 and 3), the filling pipe 12 in the pump tower 10 is spaced apart from the main pipes 11 and 13 and does not serve as a structural member, in the present invention The filling pipe 120 serves as a main structural member.

In the present invention, in order to be able to serve as a structural member of the filling pipe 120 , firstly, the diameter of the filling pipe 120 is designed to be larger than the fluid flow capacity, and secondly, a bellows at the upper end of the filling pipe 120 . (bellows) structure is applied.

First, the fluid flow capacity of the filling pipe 120 is to calculate the amount of actual flow of liquefied gas during filling (loading) of liquefied gas, depending on what the filling facility is and the design capacity of the liquefied gas storage tank In the present invention, the fluid flow capacity of the filling pipe is calculated in consideration of the flow rate level according to the filling facility and the capacity of the liquefied gas storage tank, and the diameter of the filling pipe 120 is compared to the calculated fluid flow capacity design big.

In addition, the present invention is not limited to simply expanding the diameter of the filling pipe 120, and designing the expanded filling pipe 120 in a double pipe structure and using the external pipe as a spraying pipe. have. That is, in the present invention, the filling pipe 120 may be designed in a double pipe structure to provide a spraying function in a merged form. This will be described in more detail later with reference to FIGS. 9 and 10 .

Next, as shown in FIG. 8 , a bellows 141 is installed in the connection part through which the filling pipe 120 is inserted through the dome housing 110 , and the bellows 141 is held in the peripheral portion of the bellows 141 . An auxiliary support member 142 is additionally installed so as to give it, and the upper end of the filling pipe 120 may be fixed to the auxiliary support member 142 by a U-bolt 143 .

As such, the present invention 1) designing the filling pipe 120 to be larger than the actual fluid flow capacity, and 2) applying a bellows structure to the upper end of the filling pipe 120, the filling pipe 120 is a heat shrink problem overcoming the obstacles and allowing it to play the role of a major structural member.

Referring back to FIG. 6, the discharge pipe 130 uses the liquefied gas stored in the liquefied gas storage tank as fuel for the engine provided in the ship or liquefied gas when the liquefied gas stored in the liquefied gas storage tank is unloaded overboard. may be provided as a movement path of

That is, in the present invention, the discharge pipe 130 can serve both as a fuel supply pipe for supplying liquefied gas as fuel of the engine and as an unloading pipe for unloading liquefied gas overboard. have.

In the large LNG storage tank provided in the conventional LNGC, a pipe/pump for fuel supply, which is separate from the pipe/pump for unloading installed in the pump tower, is provided separately. This is because the capacity of the fuel supply pipe/pump is much smaller than the capacity of the pipe/pump provided for unloading, so it is not suitable for use for unloading.

However, as the present invention is applied to a small/medium liquefied gas storage tank, a pipe and a pump are not separately provided by dividing the purpose for unloading and fuel supply, but a discharge pipe 130 and a cargo pump (CP) to be described later. can be used to perform both fuel supply and unloading.

In particular, when the present invention is applied to a fuel tank that stores liquefied gas as fuel, the unloading function is not required except in special situations such as emergency situations, so the discharge pipe 130 and the cargo pump (CP) are liquefied gas Its main purpose is to supply as fuel for the engine, so it can be equipped with a small capacity to meet the needs of the engine.

The discharge pipe 130 may be provided as a pair as a concept of redundancy in preparation for failure, and may be provided to face each other on both sides of the filling pipe 120 as a center.

A cargo pump (CP) is installed in the lower portion of the discharge pipe 130 to discharge the liquefied gas stored in the liquefied gas storage tank to the outside. The cargo pump CP may be mounted and fixed to a cradle 320 for fixing the pump to be described later.

The present invention applies a bellows structure to the connection of the discharge pipe 130 and the cargo pump (CP) to absorb the thermal stress acting on the discharge pipe 130, or the lower end of the discharge pipe 130 It can be configured as a U-shaped curved pipe.

Hereinafter, with reference to FIG. 7, the remaining pipes provided in the pump tower 100 according to the present invention will be described.

The pump tower 100 according to the present invention is connected to one side of the dome housing 110 through a gas main pipe 151 for discharging boil-off gas (BOG) generated in the liquefied gas storage tank, and liquefied gas. It may further include a gas return pipe 152 for returning the boil-off gas discharged from the storage tank to the inside of the tank. BOG discharged through the gas main pipe 151 may be supplied as fuel for an engine provided in the ship or may be discharged to the outside through a vent mast.

In addition, the pump tower 100 according to the present invention is installed at the ends of the pressure maintaining pipes 161 and 162 provided to maintain the inside of the liquefied gas storage tank within the allowable pressure, and the pressure maintaining pipes 161 and 162. When it is necessary to offset the negative pressure of the pressure valve, tubing for discharging boil-off gas or a manifold 163 to which a piping line is connected may be further included.

The above-described gas main pipe 151 and gas return pipe 152 are provided for the purpose of discharging or introducing boil-off gas when necessary, and in the case of the pressure maintenance pipes 161 and 162, the purpose of protecting the tank in case of an emergency. will be provided with

In addition, the pump tower 100 according to the present invention, the first and second sampling pipes 171 and 172 for extracting a part of the liquefied gas stored in the liquefied gas storage tank for the purpose of sampling, and the liquefied gas The first and second temperature measuring pipes 173 and 174 for measuring the temperature of the liquefied gas stored in the storage tank, and a pair of leveling pipes 175 for measuring the level of the liquefied gas stored inside the liquefied gas storage tank , 176) may further include.

Here, the first sampling pipe 171 is to extract liquefied gas from the middle point of the liquefied gas storage tank, and the second sampling pipe 172 is to extract liquefied gas from the bottom point of the liquefied gas storage tank. can be installed.

Similarly, the first pipe 173 for temperature measurement is to measure the temperature of the liquefied gas at the middle point of the liquefied gas storage tank, and the second pipe 174 for temperature measurement is liquefied at the lower point of the liquefied gas storage tank. It can be installed to measure the temperature of the gas.

In any one of the pair of leveling pipes 175 and 176, a level alarm for generating an alarm by detecting when the internal water level of the liquefied gas storage tank increases to a certain level or more may be installed.

In addition, the pump tower 100 according to the present invention, the pipe 180 for the electric cable installed inside the cable for supplying power to the cargo pump (CP), and the removal of gas accumulated in the liquefied gas storage tank and _{Oxygen (O 2} ) in the liquefied gas storage tank may further include a purging / sampling pipe 190 installed for the purpose of gas sampling.

As described above, the present invention integrates the existing liquid dome and gas dome into one dome structure (integrated dome), and optimally arranges various pipes related to handling of liquefied gas and vaporized gas in the dome structure, Positive effects such as increased convenience and simplified installation can be achieved.

Hereinafter, with reference to FIGS. 9 and 10, the filling pipe 120 of the double pipe structure in which the spraying function is incorporated in the pump tower 100 according to the present invention will be described in more detail.

The present invention provides a design suitable for a medium/small liquefied gas storage tank, and has an integrated dome in which the existing liquid dome and the gas dome are integrated, and thus the spraying pipe that has been disposed on the gas dome side Included in the configuration of the pump tower (100).

That is, the present invention integrates the liquid dome and the gas dome into one dome structure, so that the structure of the pump tower 100 can be provided with all of the essential components that have been respectively arranged in the existing liquid dome and gas dome. designed in the form.

In particular, in the present invention, in designing the filling pipe 120 to a size larger than the flow rate (fluid flow capacity) of the liquefied gas actually flowing therein so that the filling pipe 120 can serve as a main structural member, the filling pipe 120 is double-piped By designing the structure and using the outer pipe as the spraying pipe 122 , it is characterized in that the loading function and the spraying function are merged into the filling pipe 120 .

9 and 10, the filling pipe 120 according to the present invention is connected to an external loading device and is installed to surround the inner tube 121 and the inner tube 121 receiving liquefied gas supplied with the spray. an upper injection pipe provided in a double pipe structure, including the Ing pipe 122; and a lower injection pipe 123 connected to the lower end of the upper injection pipe and communicating with the inner pipe 121 to receive the liquefied gas supplied to the inner pipe 121 and fill the liquefied gas storage tank.

Here, the spray pipe 122 and the lower injection pipe 123 constituting the outer pipe are designed to have a larger diameter than the actual fluid flow capacity, and the inner pipe 121 can be designed to have a size corresponding to the actual fluid flow capacity. have.

A first liquefied gas inlet 121a is formed at one end of the inner tube 121 protruding to the outside of the dome housing 110 . The first liquefied gas inlet 121a is a place connected to an external loading device when loading (loading) liquefied gas to the liquefied gas storage tank.

The spray pipe 122 is formed on the outer periphery of the inner tube 121 so that a space is formed between the inner tube 121 and the second liquefaction on one side of the portion protruding to the outside of the dome housing 110 . A gas inlet 122a is formed.

That is, in the present invention, the spraying pipe 122 receives the liquefied gas through a separate liquefied gas inlet path from the first liquefied gas inlet 121a to which the liquefied gas is supplied when loading the liquefied gas, and injects the liquefied gas into the storage tank. can be supplied in this way.

To this end, the pump tower 100 according to the present invention includes an expansion pipe 124 connected to the lower end of the spraying pipe 122 in a cylindrical shape, and a plurality of pipes formed along the circumference of the expansion pipe 124 . It may include a plurality of injection nozzles 126 for each injection unit 125, and each injection unit 125.

As shown in FIG. 10, as the spray pipe 122 integrally formed with the filling pipe 120 is disposed in the central part of the pump tower 100, radially installed around the expansion pipe 124 The injection unit 125 is disposed between adjacent pipes.

In consideration of this, in the present invention, by giving a predetermined angle to the injection nozzle 126 formed in the injection unit 125, the liquefied gas supplied through the spraying pipe 122 is evenly injected into the liquefied gas storage tank. can In this case, the predetermined angle may mean an angle in which the injection direction of the injection nozzle 126 is directed toward an empty space inside the liquefied gas storage tank, rather than toward an adjacent pipe.

The injection nozzles 126 may be arranged in two or more rows to inject the liquefied gas into the storage tank at a wider injection angle, and in this case, the injection nozzles 126 arranged in two or more rows are separated from the expansion pipe 124 . The injection unit 125 may have opposite angles with respect to an imaginary line along the protruding direction. In addition, the injection nozzle 126 may be formed in two or more layers on the injection unit 125 . 10 shows an embodiment in which the injection nozzles 126 formed in three layers are arranged in two rows.

In addition, the injection nozzle (126-a) is additionally installed at the lower portion of the expansion pipe 124 and the lower portion of the injection unit 125, so that it can be used not only for spraying liquefied gas but also for draining.

The spraying part 125 formed at the lower end of the spraying pipe 122 is. It may be disposed on the upper side of the storage tank so as to inject the liquefied gas into the inner upper region of the liquefied gas storage tank. Specifically, the injection unit 125 may be located close to the lower level of the primary insulation layer (primary insulation) installed on the ceiling of the liquefied gas storage tank.

The present invention can lower the internal temperature of the liquefied gas storage tank by injecting the liquefied gas into the liquefied gas storage tank through the spraying pipe 122 . The injection of the liquefied gas through the spraying pipe 122 as such is evaporated in the liquefied gas storage tank in order to cool down the inside of the tank before the shipment of the liquefied gas is made in the liquefied gas storage tank, or during the operation of the ship. It can be carried out to suppress the generation of gas.

According to the present invention in which the filling pipe 120 is provided in a double pipe structure to serve as the spraying pipe 122 as described above, the space for the installation of the spraying pipe 122 can be minimized, The size of the dome can be reduced, which leads to a reduction in the amount of heat intrusion into the liquefied gas storage tank, thereby minimizing the amount of liquefied gas lost due to boil-off gas.

In addition, according to the present invention, as the spraying pipe 122 is disposed on the directly upper part of the pump tower 100, it is possible to effectively cool the pump tower 100 during shipment of liquefied gas, so that the filling pipe 120 ), which has the effect of minimizing the thermal shock when liquefied gas flows.

In addition, according to the present invention, it is possible to omit the fit-up operation of the filling pipe 120 and the spraying pipe 122 and the support welding operation for the structure, thereby increasing the convenience for welding and on-site construction time. It is possible to achieve the effect of improving productivity by shortening the

On the other hand, the medium/small liquefied gas storage tank to which the present invention is applied is less affected by sloshing, so it is not significantly restricted by the trim conditions of the vessel. Therefore, unlike the existing restrictions on the arrangement position of the liquid dome or gas dome, in the present invention, the position of the integrated dome can be freely arranged on the upper part of the storage tank. However, in consideration of the function of the spraying pipe 122 described above, it may be most advantageous to position the integrated dome in the upper center of the liquefied gas storage tank.

Hereinafter, the lower structure of the pump tower 100 according to the present invention will be described with reference to FIGS. 11 and 12 .

First, referring to FIG. 11 , in the present invention, the filling pipe 120 is disposed in the central portion of the pump tower 100 to serve as a main structural member, and the pipes 173, which are installed in the periphery of the filling pipe 120 , 174, 175, 176, 180 are fixed and supported on the support frame (S) installed on the outer peripheral surface of the filling pipe (120).

At this time, the present invention is to prevent the other pipes (173, 174, 175, 176, 180) from being affected when heat shrinkage occurs in the filling pipe 120 serving as a main structural member, the pipes (173, 174, 175 , 176 , and 180 are slidably supported on the filling pipe 120 .

Specifically, the support frame S is attached to the outer circumferential surface of the filling pipe 120 by welding, and may include an insertion hole through which the corresponding pipe is inserted. The pipes 173 , 174 , 175 , 176 , and 180 supported by the support frame S are supported only in the horizontal direction so as to be slidable in the vertical direction within the insertion hole, that is, without restraint in the vertical direction. At this time, the insertion hole formed in the support frame (S) is formed in a size corresponding to the diameter of the pipe to be fixed, and a sliding pad that prevents friction when sliding is attached to the inner circumferential surface to induce smooth sliding of the pipe. can The sliding pad may be made of a high-density polyethylene (HDPE) material.

11 and 12, the lower end of the pump tower 100 according to the present invention may be coupled to the housing 300 for fixing the pump tower. The housing 300 for fixing the pump tower is directly fixed and supported on the base support 200 to be described later.

The housing 300 for fixing the pump tower can be produced by being integrally coupled when the pump tower 100 is manufactured, and the liquefied gas is stored by being fixed on the base support 200 while being coupled to the pump tower 100 . The mounting operation of the pump tower 100 in the tank can be made simply.

That is, in the present invention, the housing 300 for fixing the pump tower is a configuration that is provided so that the mounting of the pump tower 100 in the liquefied gas storage tank can be made easily, and the housing 300 for fixing the pump tower is the base support 200 . The content fixed on the phase will be described in more detail later with reference to FIGS. 13 to 16 .

The housing 300 for fixing the pump tower is coupled to the lower end of the filling pipe 120 serving as a main structural member in the pump tower 100 of the present invention. The housing 300 for fixing the pump tower may be provided as a hexahedral structure in which a space is formed, and the inner space communicates with the filling pipe 120 . Therefore, the liquefied gas supplied through the filling pipe 120 may be delivered to the housing 300 for fixing the pump tower.

And an injection hole 310 is formed at the lower end of the housing 300 for fixing the pump tower so that the liquefied gas delivered through the filling pipe 120 can be supplied into the liquefied gas storage tank. The injection hole 310 may be formed on at least two or more of the four sides of the housing 300 for fixing the pump tower, and may be formed on all four sides.

In the present invention, the housing 300 for fixing the pump tower is preferably made of stainless steel (SUS) or low-temperature steel to support the load acting on the pump tower 100 and at the same time withstand the cryogenic temperature of the liquefied gas.

11 and 12, a cradle 320 for fixing the pump may be installed on one side of the housing 300 for fixing the pump tower to support the cargo pump CP described above.

The cradle 320 for fixing the pump is installed on one side of the housing 300 for fixing the pump tower, and securing the installation space of the fixing device 400 to be described later in the central part from one side of the housing 300 for fixing the pump tower It may be formed to protrude from both edges while leaving for.

By this structure, the cargo pump (CP) provided in the pump tower 100 is arranged eccentrically to one side with respect to the filling pipe 120 disposed in the central portion.

Hereinafter, a structure in which the pump tower 100 is fixed and supported by the base support 200 installed on the bottom of the liquefied gas storage tank will be described with reference to FIGS. 13 to 16 .

First, in the present invention, the base support 200 may be provided in the form of a cylinder having the same diameter with respect to the entire height, as shown in FIG. 15 .

The conventional base support 20 shown in FIG. 4 is designed to be suitable for supporting a large pump tower, and it is difficult to manufacture it as a cone-shaped structure, and the shape of the inner and surrounding insulation of the base support 20 is also complicated. It became a factor that lowered productivity.

However, since the present invention is applied to a medium/small liquefied gas storage tank, the sloshing load acting on the inside of the storage tank is relatively small, so it is possible to design the base support 200 in a straight tube type without an inclination. Accordingly, the time and cost required for manufacturing can be reduced.

On the outer peripheral surface of the base support 200 provided in a cylindrical shape having the same diameter, the first and second plates 201 and 202 at positions corresponding to the levels of the primary membrane and the secondary membrane, respectively. ) is formed to protrude, and the membranes are connected by welding at the corresponding level. A reinforcing member 203 for reinforcing the strength of the first plate 201 may be additionally installed between the first plate 201 and the outer peripheral surface of the base support 200 .

As described above, the present invention provides a housing 300 for fixing the pump tower that is integrally coupled to the lower end of the pump tower 100, so that the structure for supporting a device such as a pump separately on the base support 200 This does not need to be provided.

Therefore, in the present invention, the base support 200 may be disposed so that the uppermost surface is on the same plane as the primary membrane, and a fixing device 400 for fixing the housing 300 for fixing the pump tower on the upper portion of the base support 200 . No structures may be installed except for

According to the present invention as described above, since the suction port of the above-described cargo pump (CP) can be installed close to the bottom surface of the liquefied gas storage tank, it is possible to smoothly discharge even the remaining liquefied gas in the storage tank when necessary, thus Effective treatment of residual liquefied gas is possible.

13 to 16 , the liquefied gas storage tank according to the present invention may further include a fixing device 400 for fixing the housing 300 for fixing the pump tower on the base support 200 . .

The fixing device 400 is fastened to the fixed support 410 fixed by welding on the upper portion of the base support 200 and the fixed support 410 and is supported in surface contact with the side of the housing 300 for fixing the pump tower. It may include a support member 420 that does.

Referring to FIG. 14 , a more detailed structure of each member 410 , 420 constituting the fixing device 400 can be confirmed.

The fixing support 410 may be installed in each of four directions to correspond to the four sides of the housing 300 for fixing the pump tower, and a first fastening hole (bolting) for coupling with a support member 420 to be described later (bolting) 411) may be formed.

The support member 420 is formed in a direction orthogonal to the surface direction of the support plate 421 and the support plate 421 disposed so as to be in surface contact with the side surface of the housing 300 for fixing the pump tower, the fixed support 410 . and a fixing plate 422 that is bolted to it.

The fixing plate 422 may have a second fastening hole 423 formed at a position corresponding to the first fastening hole 411 formed in the fixed support 410 , and the first fastening hole 411 and the second fastening hole 411 may be formed in the fixing plate 422 . By fastening the nut in a state in which the bolt is inserted through the fastening hole 423 , the support member 420 may be firmly fixed to the fixing support 410 .

At this time, a pad 430 for a function of adjusting the gap between the support member 420 and the housing 300 for fixing the pump tower can be inserted into the surface where the side of the support plate 421 and the housing 300 for fixing the pump tower is in contact. have. The pad 430 may be made of polytetrafluoroethylene (PTFE) fibers such as Teflon.

That is, the present invention is designed to easily match the allowable tolerance by the pad 430 without additional processing, so that the fixing operation of the pump tower 100 can be completed within a short time.

On the other hand, in the fixing device 400 according to the present invention, except for the fixing support 410 fixedly installed on the base support 200 by welding, the support member 420 is to be provided as a detachable and portable member. There is an advantage in that processing and installation are easier accordingly.

That is, according to the present invention, the pump tower 100 in which the housing 300 for fixing the pump tower is integrally coupled to the lower end is lowered downward from the inside of the liquefied gas storage tank and mounted on the base support 200, then the base support By coupling the support member 420 to the fixed support 410 pre-welded on the 200, the installation operation of the pump tower 100 can be made conveniently.

In addition, in the process, as described above, as the dome housing 110 of the pump tower 100 is provided in a sleeve type, it is easy to adjust (leveling) up and down during welding, so the pump tower 100 and the base support 200 No additional work is required to fill the gap between them.

Looking at the installation process of the pump tower 100 of the present invention in more detail, it can be made of the following process.

1) First, the installation of the base support 200 on the inner wall of the hull and the installation of the surrounding insulation are performed. In this case, the fixed support 410 may be integrally welded to the upper portion of the base support 200 to be manufactured and installed.

2) And before the mounting of the pump tower 100, the coupling of the housing 300 for fixing the pump tower to the lower end of the pump tower 100 is made, at this time, the cargo pump (CP) on the cradle 320 for fixing the pump. Mounting can also be done together.

3) Next, the pump tower 100 in which the housing 300 for fixing the pump tower is coupled is mounted in the liquefied gas storage tank. At this time, the dome housing 110 of the pump tower 100 may be welded to the opening of the integrated dome, and the pump tower 100 may be leveled by adjusting the welding portion of the dome housing 110 up and down. Therefore, additional work is not required to match the gap between the pump tower 100 and the base support 200 .

4) Finally, the operation of fixing the lower end of the pump tower 100 is made. This may be accomplished by pressing the four sides of the housing 300 for fixing the pump tower by the fixing device 400 in all directions, and more specifically, a support member for supporting the housing 300 for fixing the pump tower in surface contact. It may be made by fastening the 420 to the fixed support 410 previously welded on the base support 200 .

According to the fixing and supporting structure of the pump tower 100 according to the present invention, a structure such as the base plate 15 provided at the lower end of the conventional (see FIG. 5) pump tower 10 is not required. That is, the pump tower 100 according to the present invention is suitable for the design of a medium/small liquefied gas storage tank because the weight is relatively reduced compared to the existing pump tower structure requiring a base plate.

In addition, according to the installation process of the pump tower 100 according to the present invention, the installation process is greatly simplified by reducing the additional installation M/H (Man Hour) in the subsequent process compared to the existing one, and the working time in the enclosed area is shortened. It works.

The present invention is not limited to the described embodiments, and it is apparent to those skilled in the art that various modifications and variations can be made without departing from the spirit and scope of the present invention. Therefore, it should be said that such modifications or variations belong to the claims of the present invention.

100: pump tower
110: dome housing
120: filling pipe
121: inner tube
122: spray pipe
123: lower injection pipe
124: expansion tube
125: injection part
126: spray nozzle
130: discharge pipe
151 gas main pipe
152: gas return pipe
161, 162: pressure maintaining pipe
163 : Manifold
171: first sampling pipe
172: second sampling pipe
173: pipe for first temperature measurement
174: pipe for second temperature measurement
175, 176: leveling pipe
180: pipe for electric cable
190: purging/sampling pipe
200: base support
300: housing for fixing the pump tower
310: injection hole
320: cradle for fixing the pump
400: fixing device
410: fixed support
411: first fastening hole
420: support member
421: support plate
422: fixed plate
423: second fastening hole
430: pad

Claims (9)

a housing for fixing the pump tower coupled to the lower end of the pipe serving as a main structural member for the load in the pump tower mounted on the liquefied gas storage tank; and
It is installed on one side of the housing for fixing the pump tower and includes a cradle for fixing the pump on which the cargo pump provided in the pump tower is mounted,
Prior to the mounting of the pump tower in the liquefied gas storage tank, the fixing of the housing for fixing the pump tower to the lower end of the pipe and the mounting of the cargo pump to the cradle for fixing the pump are preceded,
Pump tower of liquefied gas storage tank. The method according to claim 1,
As the cradle for fixing the pump is integrally coupled to the side of the pump tower, a separate structure for fixing the pump is not installed on the base support installed at the bottom of the liquefied gas storage tank to support the pump tower. characterized by,
Pump tower of liquefied gas storage tank. 3. The method according to claim 2,
The base support has an uppermost surface that is flush with the primary membrane installed in the liquefied gas storage tank, characterized in that the inlet of the cargo pump can be installed close to the bottom surface of the liquefied gas storage tank,
Pump tower of liquefied gas storage tank. 4. The method according to claim 3,
Installed on the base support, further comprising a fixing device for supporting the four sides of the housing for fixing the pump tower in surface contact,
Pump tower of liquefied gas storage tank. 5. The method according to claim 4,
The cradle for fixing the pump is characterized in that it is formed to protrude from both edges while leaving a central portion on one side of the housing for fixing the pump tower to secure an installation space of the fixing device,
Pump tower of liquefied gas storage tank. 6. The method of claim 5,
The remaining pipes disposed on the periphery of the pipe are characterized in that they are supported to be slidable on the pipe,
Pump tower of liquefied gas storage tank. 7. The method of claim 6,
The remaining pipes are supported by a support frame installed on the outer circumferential surface of the pipe, and are inserted through an insertion hole formed in the support frame to allow sliding flow in the vertical direction,
Pump tower of liquefied gas storage tank. 8. The method of claim 7,
A sliding pad for preventing friction during sliding is attached to the inner circumferential surface of the insertion hole,
Pump tower of liquefied gas storage tank. 9. The method of claim 8,
The sliding pad is characterized in that it is made of a high-density polyethylene (HDPE: High Density PolyEthylene) material,
Pump tower of liquefied gas storage tank.

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