KR101616428B1 - Degasser for mud treatment - Google Patents

Abstract

Disclosed is a gas removing apparatus for mud regeneration. According to an aspect of the present invention, there is provided a gas removing apparatus for regeneration of a mud, comprising: a tank portion accommodating the mud to separate gas in the mud; A first mud spraying portion drawn into the tank portion to spray the mud through a first discharge hole formed along the surface; A mud conveying pipe for discharging the mud dropped into the tank portion; And a gas transfer pipe for discharging the gas separated in the tank portion.

Description

{DEGASSER FOR MUD TREATMENT}

The present invention relates to a gas removing apparatus for regeneration of mud.

As depletion of underground resources on land has increased and interest in undersea resources has increased, various offshore plants are under study to develop seabed resources. Among marine plants, drilling rigs, semi-submersible drilling rigs, and jack-up rigs are examples of drilling equipment.

The drilling rig is equipped with a drill pipe with a drill bit at the end. A mud is used as the drilling fluid of the drill bit. The mud includes barite, bentonite, etc. and is stored in a mud tank mounted on the drilling rig and is supplied as a drill bit by a mud pump.

The mud discharged through the drill bit is recovered through a riser and circulated back to the mud tank via the mud regeneration system. The mud regeneration system may include a shale shaker, a sand desander, a degasser, and a fine sand deserter.

Korean Patent Publication No. 10-2011-0112636 (October 13, 2011)

The present invention is to provide a gas removing apparatus for mud regeneration capable of improving gas separation efficiency in a mud during a regeneration process of a drilling mud.

According to an aspect of the present invention, there is provided a fuel cell system comprising: a tank part capable of receiving a mud and separating gas in the mud; A first mud spraying portion drawn into the tank portion to spray the mud through a first discharge hole formed along the surface; A mud conveying pipe for discharging the mud dropped into the tank portion; And a gas transfer pipe for discharging the gas separated in the tank portion.

Here, the first mud spraying unit may include an ejection inner tube having an ejection inner hole formed with the ejection hole of the first ejection hole and an ejection outer hole formed to correspond to the ejection hole, and an ejection hole coupled to the outer peripheral surface of the ejection inner tube to be rotatable with respect to the ejection inner tube, It may include appearance.

A gas removing device for regenerating the mud includes a sensor part installed in the first mud spraying part to sense a pressure inside the first mud spraying part; And a control unit for controlling the rotation degree of the ejection outline relative to the ejection inner tube in accordance with the pressure inside the first mud ejection unit sensed by the sensor unit.

And a second mud spraying unit installed at an outer portion of the first mud spraying unit to spray the mud that has passed through the first discharge hole through a second discharge hole formed along the surface can do.

The second discharge hole may be smaller than the first discharge hole.

According to the embodiment of the present invention, the mud is sprayed through the first discharge hole of the first mud spraying portion and the particles of the mud can be dispersed, so that the gas separation efficiency in the mud during the regeneration process of the drilling mud can be improved.

1 shows a drilling rig.
2 is a view showing a gas removing apparatus for mud regeneration according to an embodiment of the present invention.
Fig. 3 and Fig. 4 show in greater detail a portion of a first mud spout in a degas regenerating apparatus for mud regeneration according to an embodiment of the present invention; Fig.

The embodiments of the present invention will now be described in detail with reference to the accompanying drawings, wherein like reference numerals refer to like or corresponding elements throughout the several views, The description will be omitted.

It is also to be understood that the terms first, second, etc. used hereinafter are merely reference numerals for distinguishing between identical or corresponding components, and the same or corresponding components are defined by terms such as first, second, no.

In addition, the term " coupled " is used not only in the case of direct physical contact between the respective constituent elements in the contact relation between the constituent elements, but also means that other constituent elements are interposed between the constituent elements, Use them as a concept to cover each contact.

1 is a view showing a drilling rig.

1, the drilling rig 10 may include a drill pipe 12 having a drill bit 11 at its end.

The drill pipe 12 can extend from the sea to the seabed, and the drill bit 11 can excavate the seabed using the rotational force. As the drilling fluid of the drill bit 11, a drilling mud may be used. The drilling mud may include barite, bentonite, and the like.

The drilling mud is supplied from the mud tank 18 to the drill bit 11 through the drill pipe 12 and is recovered through the riser 13 and circulated back to the mud tank 18 via the mud regeneration system. The mud regeneration system may include a shale shaker 14, a desander 15, a degasser 16 and a fine sand desilter 17.

The degasser 16 is provided with a degassing device for regenerating the mud according to an embodiment of the present invention to remove the gas mixed in the drilling mud collected through the riser 13. The degassing apparatus for regenerating the mud according to an embodiment of the present invention may be the degasser 16 itself or may be connected to the degasser 16 through a mud supply pipe and a mud conveyance pipe to be described later, To the gas removal apparatus for regeneration of mud according to an embodiment of the present invention.

The drilling rig 10 may be, for example, a drillship, a semi-submersible drilling rig or a jack-up rig.

2 is a view showing a gas removing apparatus for mud regeneration according to an embodiment of the present invention. 3 and 4 are views showing a part of the first muddy-out portion in more detail in the gas removal apparatus for mud reproduction according to the embodiment of the present invention.

2 to 4, the apparatus 1000 for removing mud according to an embodiment of the present invention includes a tank unit 100, a first mud spraying unit 200, a mud conveying pipe 120, And a gas transfer pipe 130, and may further include a sensor unit 300, a control unit (not shown), and a second mud spouting unit 400.

The tank part 100 is a part capable of receiving the mud A and separating the gas B in the mud A from the first mud spraying part 200 and the mud conveying pipe 120 And the gas transfer tube 130 may be combined.

In this case, the tank unit 100 can separate the gas B in the mud A using the difference in specific gravity between the mud A and the gas B. That is, the mud A relatively heavy compared to the gas B is discharged to the outside through the mud conveying pipe 120 connected to the lower portion of the tank portion 100, and is relatively lighter than the mud A May be discharged to the outside through the gas transfer pipe 130 connected to the upper portion of the tank unit 100.

In the present embodiment, the tank portion 100 separates the gas B in the mud A using the specific gravity difference between the mud A and the gas B, The principle of separation is not limited to this, and various gas separation techniques may be used.

The first mud spraying unit 200 is a portion drawn into the interior of the tank unit 100 to spray the mud A through the first discharge hole 201 formed along the surface, It is possible to scatter the mud A with a certain pressure simultaneously with the function of supplying the mud A containing the gas B. [

That is, as shown in FIG. 2, the gas removal apparatus 1000 for mud regeneration according to the present embodiment includes a first mud discharge unit 200, a first mud discharge unit 200, (A) including the bubble (B). In this case, the first mud spraying unit 200 may be configured to control whether the mud A is supplied to the tank unit 100 and the supply speed thereof, including a separate pump, a valve, and the like.

In the process of supplying the mud A to the inside of the tank 100, the mud A is sprayed through the first discharge hole 201 of the first mud spraying unit 200, The particles can be dispersed to each other so that the surface area of each particle of the mud A contacting with the outside air becomes large so that the gas B contained in the mud A can be more actively separated from the mud A .

The mud conveying pipe 120 is a part for discharging the mud A dropped into the inside of the tank part 100. The mud conveying pipe 120 passes through the first mud spraying part 200, ) To a subsequent processing apparatus.

In this case, the mud conveying pipe 120 may include a separate pump, a valve, and the like to control the discharge and discharge speed of the mud A from the tank portion 100.

The gas transfer pipe 130 is a part for discharging the separated gas B in the tank part 100. The gas transfer pipe 130 passes the gas B separated from the mud A through the first mud- .

In this case, the gas transfer pipe 130 may be combined with a separate purifier or the like for treating harmful components in the separated gas B, and may include a separate pump, a valve, (B) It is possible to control the discharge rate and discharge rate.

As described above, in the apparatus for removing mud regeneration 1000 according to the present embodiment, the mud A is sprayed through the first discharge hole 201 of the first mud spraying unit 200, The efficiency of gas (B) separation in the mud (A) during the regeneration process of the drilling mud can be improved.

Here, the first mud spraying unit 200 may include the spraying inner pipe 210 and the spraying outer pipe 220 to adjust the size of the first discharge hole 201 when necessary.

3, the spraying inner pipe 210 is a pipe formed inside the first mud spraying unit 200, and the spraying outer pipe 220 is formed on the outer side of the first mud spraying unit 200 It can be piping.

In this case, a relatively positioned portion of the first discharge hole 201 is an discharge hole of the discharge inner pipe 210, and a portion of the first discharge hole 201 that is relatively located outside the discharge hole 220 discharges the discharge outer pipe 220 It may correspond to the outer hole.

4, the discharge outer pipe 220 is coupled to the outer peripheral surface of the discharge inner pipe 210 so as to be rotatable with respect to the discharge inner pipe 210. As the discharge outer pipe 220 rotates at a constant rotation speed, The overlapping area between the discharge inner hole of the discharge inner pipe 210 and the discharge outer hole of the discharge outer pipe 220 can be changed.

Therefore, the size of the first discharge hole 201 can be easily adjusted as shown in FIGS. 3 and 4 by adjusting the rotation degree of the discharge outer pipe 220 with respect to the discharge inner pipe 210.

The sensor unit 300 is installed in the first mud spraying unit 200 to sense the pressure inside the first mud spraying unit 200. The sensor unit 300 includes a first discharge hole 201 of the first mud spraying unit 200, It is possible to detect the pressure when the mud A is ejected.

That is, since the pressure for ejecting the mud A through the first ejection hole 201 is substantially dependent on the pressure inside the first muddy-out portion 200, A) can be sensed.

The control unit (not shown) is a part for controlling the rotation degree of the ejection appearance pipe 220 with respect to the ejection inner pipe 210 according to the pressure inside the first muddy-out part 200 sensed by the sensor unit 300, The size of the first discharge hole 201 can be automatically controlled according to the pressure inside the first mud spraying unit 200.

For example, in order to more effectively disperse the particles of the mud A, it is advantageous that the pressure for ejecting the mud A through the first discharge hole 201 becomes strong. Therefore, when the pressure inside the first mud spraying unit 200 is lower than an appropriate level, the size of the first discharge hole 201 is automatically reduced, and the pressure for ejecting the mud A can be increased.

On the other hand, when the pressure inside the first mud spraying unit 200 is excessively high, overloading of various components may occur and safety problems may occur. Therefore, the size of the first discharge hole 201 is automatically increased The pressure to eject the mud (A) can be lowered.

Therefore, the apparatus 1000 for degassing mud regeneration according to the present embodiment further includes a sensor unit 400 and a control unit (not shown) so that the size of the first discharge hole 201 is automatically changed Can be controlled.

The second mud spraying unit 400 is configured to spray the mud A passing through the first discharge hole 201 through the second discharge hole 401 formed along the surface of the first mud spraying unit 400, The mud A is ejected a plurality of times, and the particles of the mud A are more dispersed.

That is, as shown in FIG. 2, the mud A having passed through the first discharge hole 201 and having some particles dispersed therein passes through the second discharge hole 401 again, and other particles can be dispersed.

As described above, the degumming apparatus 1000 for mud regeneration according to the present embodiment can more actively disperse the mud particles A through the multistage mud spraying units 200 and 400, It is possible to further improve the gas (B) separation efficiency of the gas.

The second mud spraying unit 400 may also include an ejection inner pipe 210 and an ejection outer pipe 220 as in the first mud spraying unit 200 so that the size of the second ejection hole 401 can be adjusted have.

Here, the second discharge hole 401 may be smaller in size than the first discharge hole 201. That is, the size of the second discharge hole 401 located outside the first discharge hole 201 located relatively inside can be smaller.

The mud A ejected through the first ejection hole 201 can be dispersed when passing through the first ejection hole 201. Therefore, the mud A after passing through the first discharge hole 201 may be in a state in which the particles are relatively more dispersed than before the first discharge hole 201 has passed.

Accordingly, the size of the second discharge hole 401 at the next stage may be made smaller so that the particles of the mud A after passing through the first discharge hole 201 can be more finely dispersed.

As a result, the particles can be more finely dispersed as the mud A passes through the respective discharge holes 201, 401, thereby maximizing the efficiency of gas (B) separation in the mud A.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

10: Drilling rig 11: Drill bit
12: Drill pipe 13: riser
14: rock remover 15: sand remover
16: Gas eliminator 17: Fine sand remover
18: Mud tank 100: Tank part
120: Mud conveying pipe 130: Gas conveying pipe
200: first mud spraying unit 201: first discharge hole
210: spout internal pipe 220: spout external appearance
300: sensor unit 400: second mud spraying unit
401: Second discharge hole 1000: Mud regeneration gas removal device

Claims (5)

A tank portion for accommodating the mud and capable of separating the gas in the mud;
A first mud spraying portion drawn into the tank portion to spray the mud through a first discharge hole formed along the surface;
A mud conveying pipe for discharging the mud dropped into the tank portion; And
And a gas transfer pipe for discharging the gas separated in the tank portion,
The first muddy-
An ejection inner tube in which an ejection hole of the first ejection hole is formed,
And an ejection appearance hole formed to correspond to the ejection hole and coupled to an outer peripheral surface of the ejection inner tube so as to be rotatable with respect to the ejection inner tube. delete The method according to claim 1,
A sensor unit installed in the first mud spraying unit to sense a pressure inside the first mud spraying unit; And
And a control unit for controlling the rotation degree of the jetting outer tube with respect to the jetting inner tube in accordance with the pressure inside the first mud jetting unit sensed by the sensor unit. The method according to claim 1 or 3,
And a second mud spraying unit installed at an outer portion of the first mud spraying unit to spray the mud that has passed through the first discharge hole through a second discharge hole formed along the surface of the mud spraying unit, . 5. The method of claim 4,
And the second discharge hole is formed to be smaller in size than the first discharge hole.

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