KR20150069723A - LCM Recovery Module and Mud Return System - Google Patents

Abstract

The present invention relates to a lost circulation material recovery module and a mud circulation system. The present invention enables a lost circulation material contained in mud used for a drilling process to be separately recovered in order to prevent a loss of the lost circulation material. Accordingly, the present invention prevents wasted resources and prevents an additional supply of the lost circulation material to reduce drilling cost.

Description

{LCM Recovery Module and Mud Return System}

The present invention relates to a water intake preventing agent recovery module and a mud liquid circulation system. More specifically, it is possible to separately recover the water loss preventing agent contained in the mud liquid used in the drilling process, thereby preventing loss of the water loss preventing agent, thereby preventing waste of resources, Which is capable of reducing the drilling cost by preventing additional supply of the mud liquid circulation system.

As the international phenomenon of industrialization and industry develops, the use of resources such as petroleum is gradually increasing, and thus the stable production and supply of oil is becoming a very important issue on a global scale.

For this reason, the development of the marginal field or deep-sea oil field, which had been neglected due to economic difficulties, has become economic in recent years. Therefore, along with the development of seabed mining technology, drilling rigs with drilling facilities suitable for the development of such oilfields have been developed.

Conventional submarine drilling has been mainly used for a rig ship or a fixed platform for underwater drilling which is capable of navigating only by another tugboat and performs submarine drilling with anchorage at one point of the sea using a mooring device. Recently, with the development of submarine mining technology, a floating drilling facility equipped with advanced drilling equipment and capable of moving the position has been developed and used for deep sea drilling.

These drill ships are equipped with various drilling equipment such as derrick systems, risers, and drill pipes to drill oil and gas underground. A drill pipe is used to form a borehole in the seabed. A riser is installed on the outside of the drill pipe, and the mud liquid is circulated from the drill pipe to the borehole during the borehole forming process.

1 is a schematic view of a conventional muddy fluid circulation system according to the prior art.

The mud liquid is supplied to the inner space of the drill pipe 50 from the drill pipe so as to cool and lubricate the drill bit (not shown) installed at the lower end of the drill pipe 50 in the drilling process, And then flows back through the space between the drill pipe 50 and the riser 40 after returning to the drill pipe.

At this time, in order to prevent the mud liquid from flowing out to the seafloor during the drilling process, the mud liquid is mixed with the lost circulation material (LCM), and the leakage of the mud liquid is prevented by this water loss preventing agent, .

The mud fluids recovered from the riser 40, as shown in FIG. 1, are supplied to the filtering unit (not shown) to filter the foreign matter mixed in the drilling process 10 and the mud liquid that has passed through the filtering unit 10 flows into and is activated in the active tank 20 and then circulated through the mud liquid feed pump 30 to the drill pipe 50 Flow.

The filtering unit 10 includes a primary filtration module 100 for firstly filtering the mud liquid recovered from the riser 40 and a primary filtration module 100 for filtering the mud liquid passing through the primary filtration module 100, (200), and a process tank (300) for filtering the mud liquid passing through the shale shaker (200) in a tertiary manner. The primary filtration module 100 filters relatively large foreign matter and the shale shaker 200 filters foreign matter of a relatively small size not filtered by the primary filtration module 100 and the process tank 300 is very Fine sand and gas are filtered. The process tank 300 is disposed so that the mud liquid passes sequentially through the three filtering treatment tanks 301. In the process of sequentially passing through the respective filtering treatment tanks 301, fine sand and gas are respectively filtered, Only the pure mud liquid from which all foreign substances have been removed remains in the filtering treatment tank.

The pure mud liquid generated through the filtering process flows into the active tank 20 and is activated and then supplied to the drill pipe 50 through the mud liquid supply pump 30.

Meanwhile, the water loss preventing agent mixed in the mud liquid is filtered in the filtering process of the shale shaker 200, which is a secondary filtering process. The conventional muddy liquid circulating system according to the prior art has a function of separately collecting the filtered water loss preventing agent And it is most likely to be lost after one use.

The water loss inhibitor is an expensive material and although it can be reused, if it can not be collected separately, if it is lost, a new water loss inhibitor must be supplied to the mud liquid at all times, which further increases the cost of drilling, And the like.

Korean Patent Laid-Open No. 10-2011-0112636

Disclosure of the Invention The present invention has been made to solve the problems of the prior art. It is an object of the present invention to provide a method for recovering a desorption inhibitor contained in a mud liquid used in a drilling process, Which is capable of preventing waste of resources and preventing further supply of water loss preventing agent to reduce drilling cost, and a mud liquid circulation system.

The present invention relates to a mud liquid circulation system for recovering a mud liquid used in a subsea drilling process from a riser and supplying the same to a drill pipe, the system comprising: a filtering unit for filtering foreign matter to the mud liquid recovered from the riser; An active tank through which the mud liquid passing through the filtering unit is stored and activated; And a mud liquid supply pump for pumping the mud liquid stored in the active tank and supplying the mud liquid again to the drill pipe. The filtering unit is formed so as to be able to separate and recover the dihydrate prevention agent contained in the mud liquid And the mud liquid circulation system.

Here, the filtering unit may include a primary filtration module for primarily filtering the mud liquid recovered from the riser; A shale shaker for secondarily filtering the mud liquid passing through the primary filtration module; A process tank for three-dimensionally filtering the mud liquid passing through the shale shaker; And a desorption inhibitor recovery module for separately recovering the desorption inhibitor filtered through the shale shaker.

In addition, the water loss preventing agent recovery module may include a recovery tank installed to communicate with the inner space of the shale shaker; And a transfer module for feeding and transferring the desorption inhibitor filtered through the shale shaker to the recovery tank, wherein the desorption inhibitor can be stored in the recovery tank.

In addition, the transfer module may include a flushing nozzle for spraying a fluid into the inner space of the shale shaker so that the water loss preventing agent filtered through the shale shaker is transferred to the recovery tank. And a flushing supply pump connected to the flushing nozzle through a separate flushing line to supply fluid to the flushing nozzle.

The flushing feed pump may be connected to the process tank through the flushing line to supply the flushing nozzle with the mud liquid that has passed through the process tank.

In addition, the recovery tank may be connected to the flushing supply pump through the flushing line so that the mud liquid supplied by the flushing supply pump may be supplied to the recovery tank.

According to another aspect of the present invention, there is provided a moisture loss prevention agent recovery module capable of recovering a moisture loss prevention agent contained in a mud liquid used in a seabed drilling process, wherein a fluid is sprayed to a shale shaker for filtering a mud liquid recovered through a riser, Wherein the water loss preventing agent filtered by the shale shaker is separately transported from the shale shaker and recovered.

At this time, the fluid sprayed on the shale shaker can be applied as a pure mud liquid from which foreign matters have been removed.

According to the present invention, it is possible to separately recover the water loss preventing agent contained in the mud liquid used in the drilling process, thereby preventing loss of the water loss preventing agent, thereby preventing waste of resources, It is possible to prevent the additional supply of the inhibitor and reduce the drilling cost.

1 is a schematic view of a conventional muddy fluid circulation system according to the prior art,
2 schematically illustrates a mud fluid circulation system according to one embodiment of the present invention,
FIG. 3 is a view schematically showing a configuration of a moisture loss prevention agent recovery module of a mud liquid circulation system according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used to designate the same or similar components throughout the drawings. 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.

FIG. 2 is a view schematically showing a mud liquid circulation system according to an embodiment of the present invention. FIG. 3 schematically shows a configuration of a moisture loss prevention agent recovery module of a mud liquid circulation system according to an embodiment of the present invention. Fig.

As described in the Background of the Invention, the mud liquid circulation system according to an embodiment of the present invention recovers the mud liquid used in the subsea drilling process from the riser 40 and circulates the mud liquid to the drill pipe 50, (10), an active tank (20), and a mud liquid supply pump (30).

The mud liquid is recovered from the riser 40 and then passed through the filtering unit 10 to filter the foreign matter. The pure mud liquid filtered through the filtering unit 10 and filtered is supplied to the active tank 20 to be activated , And the activated mud liquid supplied to the active tank 20 is again pumped by the mud liquid feed pump 30 and supplied to the drill pipe 50. The mud liquid supplied to the drill pipe 50 is used in the drilling process and then circulated again through the riser 40 and through the filtering unit 10. [

At this time, the filtering unit 10 according to the embodiment of the present invention is formed so as to be able to separate and recover the dihydrate inhibitor contained in the mud liquid.

Therefore, unlike the conventional art, the circulation system for circulating mud according to an embodiment of the present invention can separately recover the circulation-preventing agent contained in the mud liquid by the filtering unit 10, thereby preventing loss of the circulation- Accordingly, it is possible to prevent waste of resources and to prevent additional supply of water loss preventing agent, thereby reducing drilling cost.

In more detail, the filtering unit 10 includes a primary filtration module 100 for firstly filtering the mud liquid recovered from the riser 40, and a secondary filtration module 100 for filtering the mud liquid passing through the primary filtration module 100 A shake shaker 200, a process tank 300 for filtering the mud liquid passing through the shale shaker 200 in a tertiary manner, and a recovery preventing agent recovery module 300 for separately recovering the filtration agent filtered through the shale shaker 200. [ (400).

The primary filtration module 100 filters relatively large foreign matter and the shale shaker 200 filters foreign matter of a relatively small size not filtered by the primary filtration module 100 and the process tank 300 is very Fine sand and gas are filtered. The process tank 300 is disposed so that the mud liquid passes sequentially through the three filtering treatment tanks 301. In the process of sequentially passing through the respective filtering treatment tanks 301, fine sand and gas are respectively filtered, Only the pure mud liquid from which all foreign substances have been removed remains in the filtering treatment tank.

The pure mud liquid generated through the filtering process flows into the active tank 20 and is activated and then supplied to the drill pipe 50 through the mud liquid supply pump 30.

At this time, the water loss preventing agent contained in the mud liquid is filtered in the course of passing through the shale shaker 200 as described in the background art. The water loss preventing agent recovery module 400 according to an embodiment of the present invention is a shale shaker 200 can be separately recovered.

The recovery module 400 includes a recovery tank 410 installed to communicate with the inner space of the shale shaker 200 and a desalination inhibitor filtered through the shale shaker 200 to the recovery tank 410 And a transfer module 420 for transferring the transfer material. Thus, the water loss preventing agent filtered by the shale shaker 200 is transferred by the transfer module 420 and stored in the recovery tank 410.

The transfer module 420 includes a flushing nozzle 421 for spraying a fluid into the inner space of the shale shaker 200 so that the water loss preventing agent filtered through the shale shaker 200 is transferred to the recovery tank 410, And a flushing supply pump 423 connected to the flushing nozzle 421 through a separate flushing line 422 to supply fluid to the flushing nozzle 421.

3, the shale shaker 200 includes a plurality of filters 210 and 220 in an inner space. In the first filter 210 located upstream in the flow direction of the mud liquid, The foreign substance P having a large size is filtered, and the water dissipation inhibitor M passes through the first filter 210 without being filtered. The water loss preventing agent M is filtered by the secondary filter 220 located downstream of the primary filter 210 along the flow direction of the mud liquid and remains in the secondary filter 220.

The flushing nozzle 421 is mounted in the inner space of the shale shaker 200 to be filtered by the secondary filter 220 and directed toward the secondary filter 220 to transfer the remaining water loss preventing agent M to the recovery tank 410. [ Spray fluid. The water loss preventing agent M remaining in the secondary filter 220 by the fluid injection of the flushing nozzle 421 is transported and stored in the recovery tank 410 communicated with the shale shaker 200. The injection direction of the fluid by the flushing nozzle 421 may be formed to be inclined in the corresponding direction so that the water loss preventing agent M remaining in the secondary filter 220 is smoothly transferred to the recovery tank 410.

In this manner, the water loss preventing agent M stored in the recovery tank 410 may be configured to be mixed again into the mud liquid through a separate supply line, and may be recovered separately and used according to the needs of the user.

The flushing nozzle 421 is connected to the flushing supply pump 423 through the flushing line 422 and is configured to inject the fluid supplied through the flushing supply pump 423, May be configured to supply the mud liquid that has passed through the process tank (300) to the flushing nozzle (421). That is, since the fluid to be sprayed for transferring the water loss preventing agent M should not be mixed with other foreign substances, the fluid passing through the process tank 300, more specifically, through the process tank 300, And the purified mud liquid stored in the final filtering processing tank 301 can be supplied as the injection fluid. Of course, the pure mud liquid may be supplied or pure water may be supplied. However, in this case, a separate mud liquid supply tank or the like is additionally required. Therefore, in order to simplify the structure, It is preferable that the pure mud liquid is supplied again.

According to this structure, a very small amount of pure mud liquid is present together with the water dissipation inhibitor (M) in the recovery tank 410 and the water dissipation inhibitor (M) is mixed with the mud liquid again in the drilling process. The reusable function is maintained well even if the water-loss preventing agent (M) and the mud liquid are mixed in the recovery tank (410).

Meanwhile, the pure mud liquid supplied through the flushing supply pump 423 may be supplied to the recovery tank 410 as well as the flushing nozzle 421 as shown in FIG. By supplying the pure mud liquid to the recovery tank 410 in this way, the stirring action can be generated in the recovery tank 410, so that the hardening of the water dissipation inhibitor M can be prevented, and uniform mixing with the mud liquid Distribution state can be achieved.

The flushing line 422 can be configured to connect the flushing supply pump 423 and the flushing nozzle 421 as well as to connect the flushing supply pump 423 and the recovery tank 410. [

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

10: Filtering unit 20: Active tank
30: Mud liquid supply pump 40: riser
50: drill pipe 100: primary filtration module
200: shale shaker 300: process tank
400: Recovery recovery module
410: Recovery tank 420: Feed module
421: Flushing nozzle 422: Flushing line
423: Flushing feed pump

Claims (8)

A muddy liquid circulating system for recovering a mud liquid used in a subsea drilling process from the riser and supplying the recovered mud liquid to a drill pipe,
A filtering unit for filtering foreign matters to the mud liquid recovered from the riser;
An active tank through which the mud liquid passing through the filtering unit is stored and activated; And
A mud liquid supply pump for supplying the mud liquid stored in the active tank to the drill pipe again,
Wherein the filtering unit is formed so as to be separately recovered by filtering the water loss preventing agent contained in the muddy liquid. The method according to claim 1,
The filtering unit
A primary filtration module for primarily filtering the mud liquid recovered from the riser;
A shale shaker for secondarily filtering the mud liquid passing through the primary filtration module;
A process tank for three-dimensionally filtering the mud liquid passing through the shale shaker; And
A recovery device for recovering a lost water loss preventing agent filtered through the shale shaker,
Wherein the mud fluid circulation system comprises: 3. The method of claim 2,
The sucking loss preventing agent recovery module
A recovery tank installed to communicate with the inner space of the shale shaker; And
A transfer module for feeding and transferring the water loss preventing agent filtered through the shale shaker to the recovery tank,
, And the sucking loss preventing agent is stored in the recovery tank. The method of claim 3,
The transfer module
A flushing nozzle for spraying the fluid into the inner space of the shale shaker so that the water loss preventing agent filtered through the shale shaker is transferred to the recovery tank; And
A flushing supply pump connected to the flushing nozzle through a separate flushing line to supply fluid to the flushing nozzle,
And a circulation system for circulating the circulating fluid. 5. The method of claim 4,
Wherein the flushing feed pump is connected to the process tank through the flushing line to supply the flushing nozzle with the mud liquid that has passed through the process tank. 6. The method of claim 5,
Wherein the recovery tank is connected to the flushing supply pump through the flushing line so that the mud liquid supplied by the flushing supply pump can also be supplied to the recovery tank. Claims [1] A recovery module for recovering a desorption inhibitor contained in a mud liquid used in an underwater drilling process,
Wherein the fluid is sprayed to a shale shaker for filtering the mud liquid recovered through the riser to separate and recover the desorption inhibitor filtered by the shale shaker separately from the shale shaker. 8. The method of claim 7,
Wherein the fluid injected into the shale shaker is applied as a pure mud liquid from which foreign matter has been removed.

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