KR20220092066A - Cofferdam Heating Tower - Google Patents

Abstract

A cofferdam heating tower is disclosed. The present invention, as a means for heating the inside of a cofferdam disposed in front or rear of a liquefied gas storage tank in a ship equipped with a membrane type liquefied gas storage tank, provides a cofferdam heating tower characterized in that a heating pipe for receiving a heat medium into a pipe and supplying heat to the inside of a cofferdam and a return pipe for discharging the heat medium supplied to the heating pipe are manufactured as an integral structure and installed inside the cofferdam in a tower format. The cofferdam heating tower of the present invention, implemented in a tower format, can maintain the inside of the cofferdam at an appropriate temperature in a short time by dissipating heat into the inside of the cofferdam by utilizing the large cross-sectional area of the heating pipe, and has a simplified installation structure, which has the effect of increasing the convenience of the installation work due to the reduction in quantity and welding work.

Description

Cofferdam Heating Tower {Cofferdam Heating Tower}

The present invention relates to a cofferdam heating tower, and more particularly, to a cofferdam heating tower installed in a heating tower method as a means for heating the inside of a cofferdam of a ship having a liquefied gas storage tank.

In general, cargo ships such as LNGC (LNG Carrier) or LNG RV (LNG Regasification Vessel) have storage tanks (commonly referred to as 'cargo holds') to store cryogenic liquefied natural gas (LNG). provided

These LNG storage tanks can be classified into an independent type and a membrane type depending on whether the load of cargo acts directly on the insulation material. A bulkhead having the same shape as the cross-sectional shape of the storage tank is provided for each front and rear.

A space partitioned by such a bulkhead is usually called a cofferdam. In the space of the cofferdam, a separate system is configured to protect and withstand the steel plate from internal temperature change of the storage tank and leakage of LNG.

In addition, the temperature of the interior of the cofferdam should be kept constant in accordance with the standards required by the classification regulations. In general, a method of arranging a heating coil by installing a pipe inside the cofferdam is used. .

In Korean Patent Laid-Open No. 10-2006-0124860 regarding 'Cofferdam Heating Means for Liquefied Natural Gas Carrier', a zigzag heating coil is disposed on one bulkhead of the cofferdam. According to this prior art, the heating coil is In order to be installed in a zigzag form, a structure penetrating a plurality of pipes is included, and various problems may occur due to the penetrating structure.

Specifically, in the prior art, it is necessary to form a number of holes on the pipe according to the pipe penetration structure of the heating coil, so structural reinforcement is required. .

In addition, in the prior art, when corrosion occurs around the pipe hole during the pipe installation process, there are a number of factors that reduce the efficiency of the work, such as a passivation work to remove it is additionally required.

Republic of Korea Patent Publication No. 10-2006-0124860 (2006.12.06)

As described above, the present invention is to solve various problems that occur due to the excessive installation time required for the heating coil method using the existing piping and the generation of holes in the piping installation process. Specifically, the conventional heating coil method is heated. It aims to provide a cofferdam heating tower that can simplify installation by changing and applying a tower method, and significantly increase work convenience due to reduction in quantity and welding work.

According to one aspect of the present invention for achieving the above object, in a ship equipped with a membrane type liquefied gas storage tank, it is manufactured as an integral tower structure inside a cofferdam disposed in front or rear of the liquefied gas storage tank and is vertical A cofferdam heating tower installed in the direction, comprising: a heating pipe receiving a heating medium and supplying heat to the inside of the cofferdam which is disposed in front or behind the liquefied gas; and a return pipe for discharging the heating medium supplied into the heating pipe, a cofferdam heating tower may be provided.

The return pipe may be installed as an inner tube inside the heating pipe.

The cofferdam heating tower according to an aspect of the present invention may further include a discharge pipe for suctioning and discharging the fluid collected in a bilge well or a sump well formed under the cofferdam. have.

Cofferdam heating tower according to an aspect of the present invention, the ejector is installed on the discharge pipe to provide a discharge pressure of the discharge pipe; and a driving pipe for providing a driving pressure of the ejector.

The cofferdam heating tower according to an aspect of the present invention may further include a sounding pipe for measuring the level of the fluid collected in the bilge well or the sump well.

The cofferdam heating tower according to an aspect of the present invention may further include a guide ring installed on the outer peripheral surfaces of the heating pipe, the discharge pipe, the driving pipe and the sounding pipe to guide the installation of the pipes.

The heating pipe functions as a main structural member for supporting the load of the cofferdam heating tower, and the cofferdam heating tower according to an aspect of the present invention includes the discharge pipe, the driving pipe and the sounding pipe as the heating pipe. It may further include a support to support through.

A plurality of the supports may be installed to be spaced apart along the height direction of the cofferdam heating tower.

A cofferdam heating tower according to an aspect of the present invention is a box structure through which the heating pipe, the return pipe, the discharge pipe, the driving pipe and the sounding pipe pass, and is provided at the upper end of the cofferdam heating tower. It may further include a deck trunk fixed to the upper deck located on the upper side of the cofferdam.

After the cofferdam heating tower is manufactured as an integral tower structure, it may be installed inside the cofferdam in the hull assembly step.

The lower end of the cofferdam heating tower may be supported by a support installed on the bottom surface of the cofferdam, and the upper end may be fixed by welding the deck trunk to the upper deck side.

On the other hand, according to another aspect of the present invention for achieving the above object, as a means for heating the inside of the cofferdam disposed in the front or rear of the liquefied gas storage tank in a ship equipped with a membrane type liquefied gas storage tank, A heating pipe for supplying heat to the inside of the cofferdam by receiving the heating medium into the tube and a return pipe for discharging the heating medium supplied to the heating pipe are manufactured as an integral structure and installed inside the cofferdam in a tower form A cofferdam heating tower may be provided.

At this time, it may be configured to include a discharge pipe that suctions and discharges the fluid collected in the bilge well or sump well formed under the cofferdam as the integral tower structure.

The cofferdam heating tower may be installed in a region in which the bilge well is located and a region in which the sump well is located within the cofferdam.

The present invention provides a cofferdam heating tower of a completely new type configured in a tower shape unlike the conventional heating coil method as a means of heating a cofferdam inside a ship.

The cofferdam heating tower of the present invention is not a method of installing a heating coil in a pipe, but a method of emitting heat from the pipe itself receiving a heating medium, and can supply heat to the inside of the cofferdam by utilizing a wider cross-sectional area, Accordingly, there is an effect that the inside of the cofferdam can be maintained at a required appropriate temperature within a short time.

In addition, the cofferdam heating tower of the present invention has an effect that the installation structure is greatly simplified, so that it is possible to reduce the quantity of pipes and reinforcement materials, and the convenience of the installation work is remarkably increased due to the reduction of welding work, etc.

The effects of the present invention are not limited to the above-described effects, and other effects not mentioned will be clearly understood from the following description.

1 is a view showing the internal structure of a ship in which a cofferdam heating tower according to the present invention is installed.
2 is an enlarged view of the upper structure of the cofferdam heating tower according to the present invention.
3 is an enlarged view showing the lower structure of the cofferdam heating tower according to the present invention.

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 terminology used herein is only used to describe specific embodiments and is not intended to limit the present invention. For example, the singular expression includes the plural expression unless the context clearly dictates otherwise. In addition, terms such as “include” or “have” mean that other components may be further included, rather than excluding other components, unless otherwise stated.

The cofferdam heating tower according to the present invention described below can be applied to various ships. Here, a vessel is a membrane type storage to store LNG, as well as cryogenic liquefied gases such as LPG (Liquefied petroleum gas), LEG (Liquefied Ethane Gas), Liquefied Ethylene Gas, and Liquefied Propylene Gas. It can include all types of ships equipped with tanks, and as well as ships with self-propelled power such as the above-described LNGC and LNG RV, LNG FPSO (Floating, Production, Storage and Offloading) or LNG FSRU (Floating Storage and Regasification Unit) ) can be interpreted as including all offshore structures floating in the sea.

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.

1 is a view showing the internal structure of a ship in which a cofferdam heating tower according to the present invention is installed, and FIGS. 2 and 3 are enlarged views showing the upper and lower structures of the cofferdam heating tower according to the present invention, respectively.

Referring to the accompanying drawings, the cofferdam heating tower 100 according to the present invention is vertical to the inner space of the cofferdam C installed in the front and rear of the liquefied gas storage tank (not shown) inside the hull. can be installed.

The cofferdam heating tower 100 includes a heating pipe 110 for supplying heat to the inside of the cofferdam C by flowing a heating medium through the internal space, and a return pipe for discharging the heating medium supplied to the heating pipe 110 . 120 may be provided in the form of an integrally manufactured tower structure.

As shown in Fig. 1, the cofferdam heating tower 100 is located in the lower portion of the cofferdam C, in the area where the bilge well 10 is located and in the area where the sump well 20 is located. Each may be installed, and the discharge pipe 130 for suctioning the water collected in the bilge or sump well 20 collected in the bilge well 10 is integrated with the heating pipe 110 and the return pipe 120 . It may consist of a tower structure.

The heating pipe 110 serves to supply heat to the inside of the cofferdam C by receiving a heating medium such as glycol water. That is, the present invention is not a method of installing a heating coil in a pipe as in the prior art, but a method of emitting heat from the pipe itself receiving a heating medium, and can supply heat to the inside of the cofferdam by utilizing a wider cross-sectional area. Therefore, there is an effect that the inside of the cofferdam can be maintained at an appropriate temperature required within a short time.

A pressure pipe 111 for supplying a heating medium at a predetermined pressure is connected to the upper end of the heating pipe 110, and to the lower end of the heating pipe 110 to remove residual water in the pipe during a hydro test or maintenance. For the purpose of the drain valve (drain valve, 112) may be installed.

The return pipe 120 discharges the heating medium supplied to the inside of the heating pipe 110 back to the outside, and in the present invention, the return pipe 120 may be configured as an inner tube of the heating pipe 110 .

That is, the heating pipe 110 is configured in the form of a double tube, and the heating medium is supplied through the outer tube, and the inner tube may function as a return pipe 120 for discharging the heating medium supplied to the outer tube to the outside again.

A hole communicating with the heating pipe 110 may be formed at the lower end of the return pipe 120 , and when the heating medium is supplied from the upper side of the heating pipe 110 through the pressure pipe 111 , the heating pipe 110 ) The heating medium existing inside is pushed upward through the return pipe 120 by the new supply pressure and discharged.

The discharge pipe 130 serves to discharge the fluid collected in the bilge well 10 or the sump well 20 to the outside. That is, the discharge pipe 130 of the cofferdam heating tower 100 installed on the bilge well 10 side discharges the bilge collected in the bilge well 10, and the cofferdam heating installed on the sump well 20 side The discharge pipe 130 of the tower 100 is involved in discharging the water collected in the sump well 20 .

At this time, the present invention does not have a separate pump to discharge the fluid collected in the bilge well 10 or the sump well 20, but installs an ejector 131 on the discharge pipe 130 to increase the discharge pressure. can provide

In addition, the cofferdam heating tower 100 according to the present invention may further include a driving pipe 140 for providing a driving pressure to the ejector 131 installed on the discharge pipe 130 .

The driving pipe 140 is a pipe for providing pressure to the ejector 131 , and in the present invention, the driving pipe 140 is pulled by a fire pipe line disposed in the main passage way of the ship. can be used as

As described above, the configuration to provide the discharge pressure of the discharge pipe 130 using the ejector 131 instead of the conventional pump is the discharge pipe 130 for discharging the fluid in the bilge well 10 or the sump well 20. It is a design for easy coupling integrally to the cofferdam heating tower 100 of the present invention manufactured in a tower format.

The cofferdam heating tower 100 according to the present invention may further include a sounding pipe 150 for measuring the amount by measuring the depth of the fluid collected in the bilge well 10 or the sump well 20. .

The sounding pipe 150 may be configured to measure the water level of the bilge well 10 or the sump well 20 by lowering the weight into the pipe, and similarly to the return pipe 120 , the inside of the heating pipe 110 . It may be disposed on, but the location of the arrangement is not necessarily limited thereto.

The cofferdam heating tower 100 of the present invention may be installed inside the cofferdam C after a plurality of pipes are manufactured as an integral structure in the form of a tower from the outside as described above.

In addition, the cofferdam heating tower 100 according to the present invention includes a guide ring 160 that guides the installation of pipes in the manufacturing process, and is installed spaced apart along the height direction of the tower structure to constrain and support a plurality of piped A support 170 and a deck trunk 180 as a structure for fixing a plurality of pipes to the upper end may be further included.

The support 170 is a reinforcement for supporting a plurality of pipes constituting the cofferdam heating tower 100 . At this time, in the cofferdam heating tower 100 of the present invention, the heating pipe 110 can function as a main structural member supporting the load of the entire structure, and thus the support 170 is different from the conventional pipe reinforcement. It does not require welding, and it is possible to be provided at a minimum so as to support the remaining pipes 130 to 150 through the heating pipe 110 that can be viewed as the main pipe.

That is, the support 170 does not need to be fixed at a separate location inside the cofferdam C, and only to the extent that the remaining pipes 130 to 150 can be supported through the heating pipe 110, which is the main structural member. may be requested

The support 170 may also be installed inside the guide ring 160 , and serves to prevent the plurality of pipes from moving in the lateral direction. In addition, the support 170 may function as a heatsink plate to prevent temperature rise by dissipating heat of the plurality of pipes.

The deck trunk 180 is a box structure through which a plurality of pipes constituting the cofferdam heating tower 100 penetrate, and is inserted and welded in a sleeve type to the upper deck covering the upper side of the cofferdam C. and can be fixed.

Looking briefly at the manufacturing and installation process of the cofferdam heating tower 100 according to the present invention, the plurality of pipes described above and the guide ring 160 and support 170 for guiding and supporting these pipes and the deck trunk 180 ), after being manufactured as an integral tower structure, the cofferdam heating tower 100 can be installed into the cofferdam by using a crane when assembling the hull.

At this time, the cofferdam heating tower 100 may be supported by the support 200 installed on the bottom surface of the cofferdam C, in a state in which the cofferdam heating tower 100 is positioned on the support 200 . By welding and fixing the upper deck trunk 180 to the upper deck side, the installation and mounting of the cofferdam heating tower 100 can be completed. When the mounting of the cofferdam heating tower 100 is completed, the pipes may be connected to an external pipe to be closed.

That is, the present invention can be said to suggest a method of manufacturing the cofferdam heating tower 100 as an integral structure of the tower type, mounting it in the hull assembly stage, and then connecting the piping in the preceding design process and finishing it as a single unit. It can be installed in a simple manner by integrally mounting the manufactured tower structure, which has the effect of remarkably increasing the convenience for installation and mounting work.

In addition, in the present invention, the support 170 is between the heating pipe 110 and the remaining pipes 130 to 150 so that the remaining pipes 130 to 150 can be supported through the heating pipe 110 as the main structural member. It can be provided in a minimum, and the work can be easily completed through welding or bolting. Therefore, the present invention does not require the installation of U-bolts and other reinforcing materials required for piping installation in the conventional heating coil method, so it is possible to reduce the quantity of pipes and reinforcement materials, and to significantly reduce welding work.

In addition, various pipes provided in the cofferdam heating tower 100 of the present invention do not include a through structure as in the prior art, and the connection of these pipes can also be implemented by welding or bolting, so that the convenience for installation and welding is increased A positive effect of simplifying work in confined areas is expected.

In addition, in the present invention, in configuring the heating pipe 110 and the return pipe 120 for supplying heat to the inside of the cofferdam (C) in the form of an integral tower, the original function as a device of the cofferdam (C) In addition to having a bilge well 10 and/or sump well 20, the discharge pipe 130, driving pipe 140, and sounding pipe 150 related to suction and water level measurement, etc. are all integrated to form a single tower It is characterized in that it is manufactured as a structure.

Therefore, the present invention solves the inconvenience of having to separately configure the piping line for the suction of the bilge well or the sump well separately from the device for heating the cofferdam in the prior art, and a configuration for performing these functions By providing an integrated cofferdam heating tower 100 that can be integrated into one, the effect of reducing the quantity and increasing work convenience according to the structure simplification can be further maximized.

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. Accordingly, it should be said that such modifications or variations are included in the claims of the present invention.

10: Bilgewell
20: Sumpwell
100: cofferdam heating tower
110: heating pipe
120: return pipe
130: discharge pipe
131: ejector
140: drive pipe
150: sounding pipe
160: guide ring
170: support
180: deck trunk

Claims (14)

In a cofferdam heating tower manufactured as an integral tower structure and installed in a vertical direction inside a cofferdam disposed in front or behind the liquefied gas storage tank in a ship equipped with a membrane type liquefied gas storage tank,
a heating pipe receiving a heating medium and supplying heat to the inside of the cofferdam disposed in front or behind the liquefied gas; and
Containing a return pipe for discharging the heating medium supplied into the heating pipe,
Cofferdam Heating Tower. The method according to claim 1,
The return pipe is characterized in that it is installed as an inner tube inside the heating pipe,
Cofferdam Heating Tower. 3. The method according to claim 2,
Further comprising a discharge pipe for discharging the fluid collected in the bilge well (Bilge well) or sump well (Sump well) formed in the lower portion of the cofferdam by suction,
Cofferdam Heating Tower. 4. The method according to claim 3,
an ejector installed on the discharge pipe to provide a discharge pressure of the discharge pipe; and
Further comprising a drive pipe for providing a drive pressure of the ejector,
Cofferdam Heating Tower. 5. The method according to claim 4,
Further comprising a sounding pipe for measuring the level of the fluid collected in the bilge well or the sump well,
Cofferdam Heating Tower. 6. The method of claim 5,
The heating pipe, the discharge pipe, the driving pipe and the sounding pipe is installed on the outer peripheral surface further comprising a guide ring for guiding the installation of the pipe,
Cofferdam Heating Tower. 6. The method of claim 5,
The heating pipe functions as a main structural member supporting the load of the cofferdam heating tower,
Further comprising a support for supporting the discharge pipe, the driving pipe and the sounding pipe through the heating pipe,
Cofferdam Heating Tower. 8. The method of claim 7,
A plurality of the supports are characterized in that they are installed spaced apart along the height direction of the cofferdam heating tower,
Cofferdam Heating Tower. 8. The method of claim 7,
As a box structure through which the heating pipe, the return pipe, the discharge pipe, the driving pipe and the sounding pipe pass, the deck is provided at the upper end of the cofferdam heating tower and fixed to the upper deck located above the cofferdam. further comprising a trunk,
Cofferdam Heating Tower. 10. The method of claim 9,
After the cofferdam heating tower is manufactured as an integral tower structure, it is characterized in that it is installed inside the cofferdam in the hull assembly step,
Cofferdam Heating Tower. 11. The method of claim 10,
The lower end of the cofferdam heating tower is supported by a support installed on the bottom surface of the cofferdam, characterized in that the upper end is fixed by welding the deck trunk to the upper deck side,
Cofferdam Heating Tower. As a means for heating the inside of a cofferdam disposed in front or rear of the liquefied gas storage tank in a ship equipped with a membrane type liquefied gas storage tank,
A heating pipe for supplying heat to the inside of the cofferdam by receiving the heating medium into the tube and a return pipe for discharging the heating medium supplied to the heating pipe are manufactured as an integral structure and installed inside the cofferdam in a tower form to do,
Cofferdam Heating Tower. 13. The method of claim 12,
Characterized in that it is constituted by including a discharge pipe for suctioning and discharging the fluid collected in the bilge well or sump well formed under the cofferdam as the integral tower structure,
Cofferdam Heating Tower. 13. The method of claim 12,
The cofferdam heating tower is characterized in that it is installed in the area where the bilge well is located and the area where the sump well is located inside the cofferdam,
Cofferdam Heating Tower.

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