KR101271049B1 - Air conditioner and offshore structure having thereof - Google Patents

Abstract

An air conditioning apparatus and an offshore structure having the same are disclosed.
The air conditioner according to the present embodiment is manufactured in the form of wrapping the derrick mounted on the offshore structure, the upper protective wall to protect the derrick, and is produced in the form of wrapping the inner region from the top of the deck to the drill floor of the offshore structure A lower protection wall for protecting an inner region, an intermediate ceiling formed between a lower end of the upper protection wall and an upper end of the lower protection wall, and installed on the lower protection wall or the upper protection wall, and the upper protection wall, the intermediate ceiling and the lower protection wall. It may include an air conditioner for providing heating air to the interior space protected by.

Description

AIR CONDITIONER AND OFFSHORE STRUCTURE HAVING THEREOF

Embodiments of the present invention relate to an air conditioning apparatus and an offshore structure having the same.

 As the industry develops, the consumption of global resources such as petroleum is gradually increasing, and thus, stable production and supply of crude oil has emerged as an important problem. Accordingly, offshore structures such as drilling vessels with drilling equipment suitable for the development of subsea oil fields have been developed.

Such subsea drilling using marine structures can be used for rigs, rigid platforms, etc. for subsea drilling for underwater drilling with anchorage at sea using a mooring device.

Drill ships, semi-submersible rigs, TLP (Tension Leg Platform), and production storage vessels have been recently developed with hulls that can be drilled and equipped with self-propelled drilling rigs. These production storage vessels include offshore oil-drilling platforms, floating production storage offloading (FPSO), crude oil drilling vessels, gas drilling vessels and floating liquefied gas storage vessels (LNG FSRU: LNG). Floating Production Storage Offloading).

1 is a view illustrating a conventional marine structure having a derrick structure.

Referring to FIG. 1, the conventional offshore structure 100 may include a derrick structure for supporting drilling equipment.

In addition, the marine structure may have a derrick 140 installed on the drill floor 130 provided at a predetermined height through the auxiliary structure 120 on the main deck 110. This derrick 140 may support the drill rig 150.

In addition, the marine structure 100 may float on the sea through the floating equipment 160 provided in the lower portion of the main deck 110. The floating equipment 160 may include a column 161 and a pontoon 162 connecting the column 161.

Drilling riser 170 that can extend the drill of the drill rig 150 to the drilling site may be installed through the main deck 110, the protector for protecting the drilling riser on the outside of the drilling riser 170 ( 180 may be provided.

When drilling is performed in the cryogenic (eg, -30 degrees Celsius) region using the marine structure 100 as described above, since the normal operating temperature condition of the drill equipment 150 is approximately -20 degrees Celsius or more. However, there is a problem that it is difficult to perform normal drilling.

Embodiments of the present invention to provide an air conditioning apparatus and an offshore structure having the same that can adjust the internal temperature of the offshore structure corresponding to the normal operating temperature conditions of the drill equipment.

According to an aspect of the present invention, it is manufactured in the form of wrapping the derrick mounted on the offshore structure and the upper protective wall for protecting the derrick, and is manufactured in the form of wrapping the inner area from the upper deck to the drill floor of the offshore structure and the inside A lower protection wall for protecting an area, an intermediate ceiling formed between a lower end of the upper protection wall and an upper end of the lower protection wall, and installed on the lower protection wall or the upper protection wall, and the upper protection wall, the intermediate ceiling and the lower protection wall. An air conditioner can be provided that includes an air conditioner that provides heating air to a protected interior space.

In addition, the upper protective wall may be provided with an upper hole in the upper end to discharge the internal air of the interior space.

In addition, the intermediate ceiling includes an extension formed horizontally at the lower edge of the upper protective wall, an inclined portion formed to be inclined toward the upper edge of the lower protective wall at the outside of the extension, and an eave portion formed to be bent downward from the outer portion of the inclined portion. In addition, a separation space for ventilation or ventilation may be provided between the cornice and the upper edge of the lower protective wall.

In addition, the lower protective wall may be provided with an air outlet for discharging the internal air of the inner space at the bottom.

The air conditioner may include a blowing fan for introducing the outside air into the inner space, and a heater for heating the outside air with the heating air and supplying the inside air to the inside space.

The air conditioner may further include a support member for installing the blower fan and the heater on the upper protective wall or the lower protective wall.

In addition, according to another aspect of the present invention, it is possible to provide an offshore structure provided with the air conditioner as described above.

When the air conditioner according to the embodiment of the present invention is installed in the offshore structure for drilling, it is possible to protect the offshore structure with the upper protective wall and the lower protective wall, and the temperature conditions for the normal operation of the drill equipment provided in the internal space of the marine structure The internal temperature of the offshore structure can be adjusted accordingly.

In addition, the internal space and the external air are circulated through the air conditioner provided in the offshore structure, thereby heating the internal space and easily discharging the combustible gas remaining in the internal space.

1 is a diagram illustrating a conventional marine structure having a derrick structure,
2 is a view illustrating an air conditioning apparatus provided in an offshore structure according to an embodiment of the present invention;
3 is a view illustrating a blower fan operation of the air conditioner according to the embodiment of the present invention;
4 is a view for explaining the heating operation of the air conditioner according to an embodiment of the present invention,
5 is a view showing the internal temperature of a conventional marine structure,
6 is a view showing the internal temperature of the marine structure according to an embodiment of the present invention.

In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. The following terms are defined in consideration of the functions in the embodiments of the present invention, which may vary depending on the intention of the user, the intention or the custom of the operator. Therefore, the definition should be based on the contents throughout this specification.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a diagram illustrating an air conditioner provided in an offshore structure according to an embodiment of the present invention.

Referring to FIG. 2, the air conditioner 200 may be installed on a deck of an offshore structure. The air conditioner 200 may include an upper protective wall 210 having an open upper hole 219, an intermediate ceiling 230, a lower protective wall 220, and an air conditioner 240.

At least one of the upper protective wall 210, the intermediate ceiling 230 and the lower protective wall 220 may be further formed with a space for accessing various equipment for the drilling operation, doors, work passages, stairs, ladders, etc. In particular, the middle ceiling 230 may be further formed with a vee-door for entering and exiting the drill pipe.

The intermediate ceiling 230 may be formed between the lower end of the upper passivation wall 210 and the upper end of the lower passivation wall 220.

The upper protective wall 210, the intermediate ceiling 230, and the lower protective wall 220 are metal panels (eg, corrugation panels made of stainless steel), which are supported by structural materials such as H beams and pipes to form wall structures or roof structures. Can be formed.

Here, the structural member may include a beam 201, a pillar 202, a joint 203, and panel fixing parts 204 and 205 using a stainless pipe.

The upper protective wall 210 may be installed in a form corresponding to the derrick form to protect the derrick (derrick) mounted on the offshore structure.

The upper protective wall 210 may have a form surrounding the derrick, and at the same time protects the derrick and at the same time to partition the external environment and the internal environment, or to prevent the outside wind, wind wave, etc. into the wall inner space. Can block function.

The lower protective wall 220 may be installed in a spaced apart form corresponding to the drill floor and the auxiliary structure, which is a corresponding structure, in order to protect the drill floor where the derrick is installed on the deck upper part of the marine structure and the space around the drill floor. have.

The lower protective wall 220 forms a shape surrounding the drill floor and the inner area of the space around the drill floor at the upper part of the deck, thereby protecting the structure from the external extreme environment and partitioning the external environment and the internal environment. It may be a function to block, or to prevent the outside wind, wind wave, etc. do not flow into the inner wall space.

The planar area surrounded by the lower passivation wall 220 described above is formed relatively wider than the planar area formed by the upper passivation wall 210. In addition, the upper passivation wall 210 may be disposed at an upper center position of the lower passivation wall 220.

Therefore, an intermediate ceiling 230 may be formed between the upper edge of the lower protective wall 220 and the lower edge of the upper protective wall 210.

The intermediate ceiling 230 may include an extension 231 horizontally formed at the lower edge of the upper passivation wall 210, an inclined portion 232 formed to be inclined toward the upper edge of the lower passivation wall 220 at the outside of the extension 231. The eaves 233 are formed to be bent downward from the outside of the inclined portion 232.

Here, a space 234 for ventilation or ventilation may be further formed between the cornice 233 and the upper edge of the lower protective wall 220.

Since the amount of air discharged through the space 234 or the upper hole 219 is relatively small, the amount of air introduced through the air conditioner 240 is relatively large, as a result, the air conditioner Relatively warm air may be present in the interior space of 200, thereby adjusting the internal temperature of the offshore structure to correspond to the normal operating temperature conditions of the drill rig.

Between the eaves 233 and the upper edge of the lower protective wall 220 may be a heat transfer-vulnerable area as a corner portion inside the air conditioner 200, as the vent or the air is discharged through the separation space 234. As a result, as the warmth of the air conditioner 240 is smoothly transferred to the heat transfer-vulnerable region, as shown in FIG. 6, the internal temperature of the marine structure or the internal temperature of the air conditioner 200 is relatively uniform. It can keep the temperature high.

In addition, the above-mentioned upper hole 219 is provided at the upper end of the upper protective wall 210, and is protected by the upper protective wall 210, the intermediate ceiling 230, the lower protective wall 220 through the upper hole 219. Air in the interior space may play a role of exhausting to the outside. That is, the upper hole 219 may also play a role of smoothly inducing the flow of the upper inner space surrounded by the upper protective wall 210 to remove the heat transfer weakened area.

To this end, the size, number, location, and shape of the upper hole 219 or the separation space 234 may be appropriately optimized or optimized through simulation or evaluation after actual placement, and thus may not be limited in this description.

For example, the lower protective wall 220 may further include an air outlet (not shown) at a lower portion thereof, and the space 234 between the eaves 233 and the lower protective wall 220 and an upper portion of the upper protective wall 210. It may play a role similar or identical to that of the hole 219.

On the other hand, the air conditioner 240 is a support structure (not shown) of the pillar 202 for the lower protective wall 220 and the support member 243 supported on the pillar 202 or the lower protective wall 220 separately installed. It may include a blowing fan 241 and the heater 242 installed based on.

The support member 243 of the air conditioner 240 may be disposed at an upper position having a predetermined height from the deck upper surface.

The predetermined height of the support member 243 of the air conditioner 240 is a simulation or actual to verify that the internal temperature of the marine structure or the internal temperature of the air conditioner 200 can be kept relatively uniform and high. Post-deployment assessments may be set to have optimized or optimized values, and may not be limited in this description.

In addition, the support member 243 of the air conditioner 240 is a pillar 202 supporting the lower protective wall 220, a pillar (not shown) supporting the upper protective wall 210, or a support structure connected to the derrick (not shown). ), A support structure (not shown) on the outside of the upper protective wall 210 or the lower protective wall 220 may be installed at a plurality of locations inside or outside the air conditioner 200.

The air conditioner 240 is a blower fan 241 for introducing the outside air and the heating air made by heating the outside air to the upper protective wall 210, the middle ceiling 230 and the lower protective wall 220 It may include a heater 242 for supplying the internal space of the air conditioner 200 is protected by. Of course, a plurality of air conditioners 240 may be installed outside the upper protective wall 210.

3 is a view illustrating an operation of a blower fan of the air conditioner according to an embodiment of the present invention, the blower fan 241 is provided with a fan on one side or both sides of the cylindrical body to bring the outside air into the interior space of the air conditioner It may be configured to inflow.

Through the blower fan 241, the outside air is introduced into the air conditioner having the upper protective wall, the middle ceiling, and the lower protective wall, thereby effectively controlling the internal temperature of the marine structure protected by the air conditioner.

In addition, Figure 4 is a view illustrating a heater operation of the air conditioner according to an embodiment of the present invention, the heater 242 is a heater (242a) through which the outside air is introduced and the heating unit for heating the incoming outside air ( 242b (eg, a steam coil) and a supply fan 242c for supplying heating air heated through the heating unit 242b to the internal space of the air conditioner 200, and an air discharge port 242d to which heating air is supplied. ) May be included.

Here, the blowing fan 241 shown in FIG. 3 may play a role of smoothly convection the heated heating air to the interior space of the air conditioner.

The heater 242 introduces external air by the rotation of the supply fan 242c, heats the external air thus introduced into the heating unit 242b, and rotates the heated heating air by the rotation of the supply fan 242c. By supplying to the internal space of the air conditioner, it is possible to effectively heat the internal space of the marine structure protected by the upper protective wall, the intermediate ceiling and the lower protective wall of the air conditioner.

The blower fan 241 and the heater 242 may be mounted on a plurality of support members 243 including a plate and a support block (see FIG. 2).

On the other hand, the air conditioner 240 as described above has been described as having a blowing fan 241 and a heater 242, but the blowing fan 241 and the heater 242 may be installed separately, respectively. In the case of the heater 242, a relatively larger number than the blower fan 241 may be installed according to the internal space structure of the marine structure such as a drill floor, an upper deck, and a main deck.

Therefore, by installing the air conditioner 200 as described above in the drilling offshore structure, it is possible to protect the offshore structure through the upper protective wall 210, the intermediate ceiling 230, the lower protective wall 220, marine structure The internal temperature of the marine structure can be adjusted to suit the temperature conditions for normal operation of the drill rig provided in the internal space of the.

In addition, by installing the air conditioner 200 as described above in the offshore structure for drilling, provided in the air conditioner 200, the separation space 234 near the cornice 233, or the upper hole ( 219, the air outlet, and the blowing fan 241 may discharge the combustible gas remaining in the internal space of the marine structure.

5 is a view showing the internal temperature of the marine structure according to the prior art, Figure 6 is a view showing the internal temperature of the marine structure according to an embodiment of the present invention.

5 and 6, the internal temperature of the marine structure according to the prior art is mostly blue low temperature while the internal temperature of the marine structure according to an embodiment of the present invention can be identified as orange or red bar Similarly, it can be seen that the relatively high temperature is kept relatively uniform.

The air conditioner according to the embodiment of the present invention can protect the various equipment installed in the offshore structure through the upper protective wall, the intermediate ceiling and the lower protective wall and at the same time can block the outside air and the internal air.

In addition, the marine structure having an air conditioner according to an embodiment of the present invention is air spaced by the separation space between the cornice and the upper edge of the lower protective wall, the upper hole provided at the upper end of the upper protective wall, or the air outlet, blower fan The internal air of the device can be vented to the outside.

On the other hand, the air conditioner that can be installed on the lower protective wall or the upper protective wall can introduce the outside air into the inner space of the air conditioner through the blowing fan, it is possible to supply the heating air into the protective wall by heating the outside air through the heater. .

Accordingly, the air conditioner according to the present embodiment satisfies the normal operating temperature condition of the drill equipment (eg, -20 degrees Celsius) when the offshore structure is drilled in cryogenic (eg, -30 degrees Celsius) region. This allows normal drilling work even in extreme environments.

As described above as a specific embodiment of the air conditioner according to an embodiment of the present invention and the marine structure having the same, but this is only an example, the present invention is not limited to this, the broadest according to the basic idea disclosed herein It should be interpreted as having a range. Those skilled in the art can easily change the material, size, etc. of each component according to the application field, and can be combined / substituted the disclosed embodiments to implement a pattern of a timeless shape, but this also does not depart from the scope of the present invention will be. It will be apparent to those skilled in the art that various changes and modifications may be readily made without departing from the spirit and scope of the invention as defined by the appended claims.

200: air conditioner 210: upper protective wall
219: upper hole 220: lower protective wall
230: intermediate ceiling 234: separation space
240: air conditioner 241: blowing fan
242: heater 242a: air inlet
242b: heating part 242c: supply fan
242d: air discharge port 243: support member

Claims (7)

An upper protective wall made of a form surrounding a derrick mounted on an offshore structure and protecting the derrick;
A lower protective wall formed to cover an inner region from an upper part of the deck of the marine structure to a drill floor, and to protect the inner region;
An intermediate ceiling formed between a lower end of the upper protective wall and an upper end of the lower protective wall;
An air conditioner installed on the lower protective wall or the upper protective wall and providing heating air to an inner space protected by the upper protective wall, the intermediate ceiling, and the lower protective wall;
The middle ceiling,
An extension part formed horizontally at the lower edge of the upper protective wall;
An inclined portion formed to be inclined toward an upper edge of the lower protective wall at an outer portion of the expansion portion;
It includes an eaves formed to be bent downward from the outside of the inclined portion,
A separation space for ventilation or ventilation is provided between the cornice and the upper edge of the lower protective wall.
Air conditioner.
The method of claim 1,
The upper protective wall has an upper hole at an upper end thereof to discharge internal air of the internal space.
Air conditioner.
delete The method of claim 1,
The lower protective wall is provided with an air outlet for discharging the internal air of the inner space at the bottom
Air conditioner.
The method of claim 1,
The air conditioner,
A blowing fan for introducing outside air into the inner space;
A heater for heating the external air with the heating air and supplying the internal air to the internal space
Air conditioner.
The method of claim 5, wherein
The air conditioner,
Further comprising a support member for installing the blowing fan and the heater to the upper protective wall or the lower protective wall
Air conditioner.
The air conditioner according to any one of claims 1, 2 and 4 to 6
Marine structures.

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