KR102033532B1 - Test Apparatus and Method for Drilling Equipment - Google Patents

Abstract

The present invention relates to a drilling apparatus test apparatus and method, by exposing the drilling equipment used in a deep sea environment, such as BOP equipment to conditions similar to the deep sea environment, it is possible to perform a variety of tests, the problem with the drilling equipment in advance It can prevent and manage, so that the installation and operation of the drilling equipment can be performed smoothly and quickly at the deep sea installation site, and the pressure vessel into which the drilling equipment is injected is formed by separating the container body and the container cover, and the upper and lower surfaces of the container cover By combining the riser and the drilling equipment, respectively, the sealing equipment can be put into the test chamber at the same time as sealing the container cover to the container body, so that the loading work on the drilling equipment can be performed conveniently and quickly. Tighten the drilling rig and riser while keeping the seal inside stable. It can provide a more stable and drilling equipment testing apparatus and method that can accurately perform a test operation.

Description

Test Apparatus and Method for Drilling Equipment

The present invention relates to drilling equipment testing apparatus and methods. More specifically, the drilling equipment used in the deep sea environment such as the BOP equipment can be exposed to the conditions similar to the deep sea environment so that various tests can be performed to prevent and manage the problems of the drilling equipment in advance. The installation and operation of the drilling equipment can be carried out smoothly and quickly, and the pressure vessel into which the drilling equipment is introduced is separated into the container body and the container cover, and the riser and the drilling equipment are respectively coupled to the upper and lower surfaces of the container cover. At the same time, the drilling equipment can be put into the test chamber while sealing the container cover to the container body, so that the loading of the drilling equipment can be performed conveniently and quickly, and the sealing state inside the pressure vessel is stably maintained. Drilling equipment and risers can be combined in one condition for more stable and accurate Drilling equipment test apparatus and method capable of performing the test operation.

As the international rapid industrialization and industry develop, the use of resources such as petroleum is gradually increasing. Therefore, stable production and supply of oil is becoming a very important problem at the global level.

For this reason, the development of marginal or deep sea oil fields, which have been neglected in recent years due to lack of economy, has become economic. Therefore, along with the development of seabed mining technology, a drilling vessel equipped with drilling equipment suitable for the development of such an oil field has been developed.

In the conventional subsea drilling, a fixed platform anchored at a point in the offshore was mainly used, but recently, a floating drilling facility capable of drilling in a deep sea of 3,000 m or more has been developed and used for subsea drilling.

These drilling facilities are equipped with various drilling-related equipment such as derrick system, riser, drill string to drill oil or gas existing in the basement of the seabed.

In recent years, as the development of deep sea oil fields is actively progressed, safety of various drilling equipments is particularly important. Among the drilling equipments, the most out-of-the-box safety equipment is the BOP (Blow out Preventer) Preventer).

BOP equipment is a device to prevent the explosion of gas in the oil well by safely removing the high-pressure gas generated during the drilling process, it is installed in the form of being connected to the upper wellhead of the sea well by the riser from the offshore drilling equipment .

These BOP equipment are designed to withstand 15,000 psi pressure at high pressures of over 3,000 m (4,300 psi) in a form suitable for deep sea environments. However, since they are not tested in the actual environment until they are installed in a deep sea well, various problems arise in actual installation site work.

In general, the BOP equipment is partially tested by applying external pressure or internal pressure separately for each component of the BOP equipment, and there is no device capable of performing such a test in a fully assembled state. As a condition, there is an urgent need for a device capable of performing various types of tests under conditions such as a real environment.

Domestic Patent No. 10-1185286

The present invention has been invented to solve the problems of the prior art, an object of the present invention is to drill drilling equipment used in a deep sea environment, such as BOP equipment by performing a variety of tests by exposing to conditions similar to the deep sea environment, drilling It provides drilling equipment test equipment and methods that can prevent and manage the problems of the equipment in advance, so that the installation and operation of the drilling equipment can be performed smoothly and quickly at actual installation sites such as the deep sea.

Another object of the present invention is to separate the pressure vessel into which the drilling equipment is put into the container body and the container cover, and to combine the riser and the drilling equipment on the upper and lower surfaces of the container cover, thereby sealing the container cover to the container body At the same time, the drilling equipment can be put into the test chamber, which makes the loading and unloading of the drilling equipment convenient and quick, and the drilling equipment and the riser can be combined while maintaining a stable sealing state inside the pressure vessel. It is to provide a drilling equipment test apparatus and method that can perform more stable and accurate test work.

The present invention is a drilling equipment test apparatus for testing drilling equipment used in a deep sea environment, the test chamber is formed so that the test target equipment can be inserted therein, the test chamber is a liquid so that the test target equipment is locked A pressure vessel stored; And an external pressure supply unit configured to increase the pressure of the liquid so that the pressure of the liquid stored in the test chamber reaches a deep sea pressure, wherein the pressure container includes a container body in which the test chamber is formed and an upper surface thereof is opened. And a container cover which is formed to be sealed and coupled to an open upper surface of the container body, wherein the test target equipment is coupled to a lower end of the container cover to be put into the test chamber while the container cover is coupled to the container body. It provides a drilling apparatus test apparatus, characterized in that.

In this case, the pressure vessel is disposed on the seabed, and the seawater may be stored in the test chamber of the vessel body in an open state of the vessel cover.

In addition, the test target equipment may be applied as a BOP equipment.

In addition, a test wellhead is fixedly mounted on the inner bottom of the container body so that the BOP device can be coupled, and the test wellhead is configured to seal the test wellhead with the container cover being sealed to the container body. It can be arranged to be coupled to.

The drilling rig test apparatus may further include a pressure resistant supply unit supplying a high pressure fluid to the test wellhead such that the internal pressure is transmitted to the BOP equipment through the test wellhead.

In addition, the robot arm may be mounted inside the pressure vessel to enable a test assistant to the test target equipment fixed to the test chamber.

In addition, a guide rail is mounted on an inner surface of the pressure vessel, and the robot arm may be coupled to be movable along the guide rail.

In addition, the container cover is connected to the lower end of the riser extending to the seabed from a separate drilling facility disposed on the sea, it can be coupled with the container body by moving downward with the riser.

In addition, a riser connection port is formed on the top of the container cover to detachably couple the riser, and the riser and the BOP equipment may be interconnected through the riser connection port.

In addition, the bottom of the container cover is formed with a BOP connection port is detachably coupled to the BOP equipment, the riser and the BOP equipment may be interconnected through the BOP connection port and the riser connection port.

In addition, a sub line connection port is formed at the upper end of the container cover so that a separate sub line disposed around the outer circumference of the riser is detachably coupled, and an operation line mounted on the BOP equipment is connected to the BOP equipment through the sub line connection port. It may be connected to the sub line.

In addition, a lower end of the container cover is formed with a BOP line connection port to be detachably coupled to the operation line of the BOP equipment, the operation line of the BOP equipment is connected to the sub line through the BOP line connection port and the sub-line connection port It can be connected with.

In addition, the drilling equipment test apparatus may be configured to further include a separate control room for controlling the operation of the BOP equipment, the external pressure supply unit and the internal pressure supply unit and monitor the operating state of the BOP equipment.

On the other hand, the present invention, drilling equipment test method for testing drilling equipment used in a deep sea environment, comprising the steps of: arranging a pressure vessel in which a test chamber is formed on the seabed; Storing liquid in the test chamber; Introducing a device under test to be immersed in the liquid stored in the test chamber; And raising the pressure of the liquid through an external pressure supply unit such that the pressure of the liquid stored in the test chamber reaches a deep sea pressure, wherein the pressure vessel is formed in a shape in which the test chamber is formed inside and the top surface is open. And a container cover which is sealed and coupled to an open upper surface of the container body, wherein the seawater is stored in the test chamber with the container cover open, and the test target equipment is a bottom of the container cover. It is coupled to provide a drilling equipment test method characterized in that the container cover is put into the test chamber in the process of being coupled to the container body.

In this case, the test target equipment is applied as a BOP equipment, and a test well head is fixedly mounted on the inner bottom of the container body so that the BOP equipment can be coupled, and the test well head is sealed by the container cover to the container body. As coupled, the BOP equipment may be arranged to couple to the test wellhead.

The drilling rig test method may further include supplying a high pressure fluid to the test wellhead through a separate internal pressure supply unit such that internal pressure is transmitted to the BOP equipment through the test wellhead. .

In addition, there is a separate control room for controlling the operation of the BOP equipment, the external pressure supply unit and the internal pressure supply unit and monitor the operating state of the BOP equipment, through which the BOP equipment is coupled to the test wellhead The combined operation test, the integrated operation test including the external pressure test and the internal pressure test for the BOP equipment can be performed.

In addition, the container cover is connected to the lower end of the riser extending to the seabed from a separate drilling facility disposed on the sea, moving downward with the riser is coupled to the container body, the BOP equipment is the Can be connected with the riser.

According to the present invention, the drilling equipment used in the deep sea environment, such as BOP equipment to be exposed to conditions similar to the deep sea environment to perform a variety of tests, to prevent and manage problems with the drilling equipment in advance to deep sea and The effect is to make the installation and operation of the drilling rig smooth and fast at the same actual installation site.

In addition, by separating the pressure vessel into which the drilling equipment is put into the container body and the container cover, and by combining the riser and the drilling equipment on the upper and lower surfaces of the container cover, at the same time the drilling equipment in the process of sealingly coupling the container cover to the container body It can be placed in the test chamber, which makes the loading of the drilling rig convenient and quick, and the drilling rig and riser can be combined while maintaining the stable sealing to the inside of the pressure vessel. It has the effect of performing test work.

1 is a conceptual diagram schematically showing the configuration of a drilling rig test apparatus according to an embodiment of the present invention,
2 is an operating state diagram schematically showing the internal configuration of the pressure vessel and the drilling equipment input process according to an embodiment of the present invention,
3 is a perspective view schematically illustrating a mutual coupling structure of a container cover, a riser, and a test target device of a pressure vessel according to an embodiment of the present invention;
4 is a cross-sectional view schematically showing the mutual coupling structure of the container cover and the riser and the device under test of the pressure vessel according to one embodiment of the present invention;
5 is an operation flowchart schematically showing the configuration of a drilling rig test method according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. First of all, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are used as much as possible even if displayed on different drawings. In addition, in describing the present invention, when it is determined that the detailed description of the related well-known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

1 is a conceptual diagram schematically showing the configuration of the drilling equipment test apparatus according to an embodiment of the present invention, Figure 2 is a schematic diagram showing the internal configuration of the pressure vessel and the drilling equipment input process according to an embodiment of the present invention FIG. 3 is a perspective view schematically illustrating a mutual coupling structure of a container cover, a riser, and a test target device of a pressure vessel according to an embodiment of the present invention, and FIG. 4 is a view showing an embodiment of the present invention. A cross-sectional view schematically showing the mutual coupling structure of the vessel cover and riser of the pressure vessel and the equipment under test.

Drilling equipment test apparatus according to an embodiment of the present invention is a device capable of performing a variety of tests by exposing the drilling equipment used in a deep sea environment to environmental conditions similar to the deep sea environment, the pressure vessel 100, the external pressure It comprises a supply unit 400.

The pressure vessel 100 has a test chamber (C) is formed in the internal space so that the test target equipment can be inserted therein, the liquid (L) is stored in the test chamber (C) to lock the test target equipment. In this case, the test target equipment is a device used in a deep sea environment, for example, the BOP equipment 200 latching (Latching) coupled to the upper wellhead of the seabed well to prevent the internal gas explosion of the bottom well can be applied. . Hereinafter, for the convenience of description, a case in which the BOP device 200 is applied as a test target device will be described as an example.

The pressure vessel 100 may be formed in a container shape of various shapes in which a test chamber C is formed therein, and is preferably formed in a cylindrical shape in consideration of the support strength for the internal pressure of the pressure vessel 100. . In addition, the pressure vessel 100 may be configured in a manner that is connected to the negative power source for corrosion protection.

In addition, the pressure vessel 100 is sealed in the open portion of the container body 110 and the container body 110, a portion of the upper surface is open so that the test chamber (C) is formed in the inner space as shown in FIG. The container cover 120 may be separated from each other. Through this structure, the liquid L can be stored and stored in the test chamber C of the container body 110 with the container cover 120 open, and the BOP equipment (with the container cover 120 open) ( 200 may be introduced into the test chamber (C) to immerse in the liquid (L). The container main body 110 may be provided with an external pressure supply port 111 and an internal pressure supply port 112 to receive pressure from the external pressure supply unit 400 and the internal pressure supply unit 500 which will be described later. In addition, the container body 110 and the container cover 120 are coupled to each other in a sealed manner so that the liquid (L) stored in the internal test chamber (C) can be maintained at a high pressure state through a pressure supply by the external pressure supply unit (400). It is desirable to be.

The external pressure supply unit 400 is configured to raise the pressure of the liquid such that the pressure of the liquid L stored in the test chamber C of the pressure vessel 100 reaches a pressure at severe conditions, for example, 4,300 psi or more. It is composed.

The external pressure supply unit 400 is an external pressure supply pump 410 that operates to supply the fluid to the test chamber C of the pressure vessel 100 at high pressure, and the high pressure fluid is supplied from the external pressure supply pump 410 to the test chamber ( It may be configured to include an external pressure supply line 420 connecting the external pressure supply pump 410 and the test chamber (C) to be supplied to C). The external pressure supply pump 410 generally supplies liquid and may be applied in the form of a compressor for supplying gas. The external pressure connection line 420 may be installed to be connected to the external pressure supply port 111 of the pressure vessel 100 from the external pressure supply pump 410. When too high pressure is formed in the inner space of the pressure vessel 100 or the inner flow path of the external pressure connection line 420, a separate pressure safety device may be provided to adjust the pressure, for example, in FIG. As shown in the figure, a separate relief valve 401 may be mounted on the external pressure connection line 420. Of course, the relief valve 401 may be mounted on one side of the pressure vessel (100).

At this time, the pressure vessel 100 is disposed on the seabed according to an embodiment of the present invention, it may be disposed in the shallow area, for example, a seabed area of about 20 m to 40 m depth for easy testing. In this case, the pressure vessel 100 may be installed in a form fixed and partially embedded in the bottom of the sea floor as shown in FIG. Of course, although not shown, it may be fixed in a form that is mounted on a separate subsea structure or fixed to the seabed through a separate mooring device.

As such, when the pressure vessel 100 is disposed on the seabed, the container body 110 of the pressure vessel 100 may be first placed on the seabed to fill the test chamber C with liquid seawater, and in this state, the BOP equipment After the 200 is put into the test chamber C, the container cover 120 may be sealed. In addition, the external pressure supply pump 410 of the external pressure supply unit 400 may also be configured in such a manner as to supply the seawater in a high pressure state, as shown in Figure 1, in this case the external pressure supply pump 410 is a separate offshore structure (P) can be fixedly installed.

On the other hand, the test well head 300 is fixedly mounted on the lower portion of the inner space of the pressure vessel 100 so that the bottom of the BOP equipment 200 is seated and coupled while the BOP equipment 200 is put into the test chamber C. The test wellhead 300 may be mounted to communicate with the pressure resistant supply port 112 described above. The test wellhead 300 is the same as the wellhead coupled to the top of the subsea well, and in one embodiment of the present invention is fixedly mounted inside the pressure vessel 100 for testing the BOP equipment 200. Therefore, the BOP equipment 200 and the test wellhead 300 are coupled to communicate with each other in the internal space in the latching state of each other.

In this case, the internal pressure supply unit 500 for supplying a high pressure fluid to the test wellhead 300 is preferably further provided such that the internal pressure is transmitted to the BOP device 200 through the test wellhead 300. The internal pressure supply unit 500 is configured to supply a high pressure fluid to reach a pressure generated when the gas explosion in the oil well, for example, 15,000 psi or more due to the high internal pressure on the BOP equipment 200.

The internal pressure supply unit 500 may be a pressure supply pump 510 that operates to supply a high pressure fluid to the test well head 300, and a high pressure fluid may be supplied from the pressure supply pump 510 to the test chamber C. It may be configured to include a pressure-resistant connection line 520 for connecting the pressure-resistant supply pump 510 and the test well head 300. The internal pressure supply pump 510 may be applied in the form of a pump for supplying a liquid, or may be applied in the form of a multi-phase pump capable of supplying a liquid and a gas at the same time to reproduce a high-pressure gas generation situation in an oil well. have. In this case, when too high a high pressure is formed in the internal space of the test well head 300 or the internal flow path of the pressure-resistant connection line 520, a separate pressure safety device may be provided to adjust the pressure. As shown in FIG. 1, a separate relief valve 401 may be mounted on the pressure resistant connection line 520.

In FIG. 1, the internal pressure supply port 112 is formed in the vessel body 110 of the pressure vessel 100, and the test well head 300 is fixedly mounted on the bottom surface of the pressure vessel 100 to supply the internal pressure supply port 112. As shown in direct communication coupled to the bar, in this case, the pressure-resistant connection line 520 may be connected to the pressure-resistant supply port 112.

At this time, the test wellhead 300 is supported through a separate wellhead support 310 as shown in FIG. 2 or spaced apart from the inner bottom surface of the pressure vessel 100 by a separate frame (not shown). It may be fixedly arranged, the test well head 300 disposed as described above is connected to the internal pressure supply port 112 and the test well head 300 to supply a high pressure fluid from the internal pressure supply unit 500. A flexible hydraulic hose (not shown) may be provided. The flexible hydraulic hose is not only formed to be flexible to bend in a curved shape as the upper and lower positions of the test well head 300 are changed as shown in FIG. 2, but also the 15,000 psi pressure supplied from the internal pressure supply unit 500. It is formed to withstand it.

In addition, the internal pressure supply pump 510 of the internal pressure supply unit 500 may be configured in such a manner as to supply the seawater in a high pressure state, such as the external pressure supply pump 410, in which case the internal pressure supply pump 510 is a separate marine It may be fixed to the structure (P).

According to this configuration, the drilling apparatus test apparatus according to an embodiment of the present invention raises the pressure of the liquid L inside the separate pressure vessel 100 to the deep sea pressure state of 3,000 m or more below the sea floor by the external pressure supply unit 400. By doing so, the external pressure test for the BOP equipment 200 can be performed. That is, when the BOP equipment 200 is exposed to deep sea pressure, it may be tested whether it is structurally stable or whether it normally operates or whether leakage occurs.

In addition, by providing an internal pressure of 15,000 psi or more to the BOP equipment 200 through the pressure supply unit 500, it is possible to perform a pressure resistance test of the deep sea environment for the BOP equipment 200. For example, an internal pressure test may be performed on rams, annulars, and various valves constituting the BOP device 200.

On the other hand, as described above, when the pressure vessel 100 is located on the seabed, it can be installed inside the pressure vessel 100 in the same manner as installing the BOP equipment 200 at the actual drilling site. That is, the BOP equipment 200 is connected to the lower end of the riser 220 extending from the separate drilling equipment 210 such as a rig to the seabed, as shown in Figure 1, and moves downward with the riser 220 to pressure The container 100 may be introduced into the container 100 and installed in a manner coupled to the test well head 300 inside the pressure container 100.

At this time, the BOP equipment 200 is mounted in a state coupled to the bottom of the container cover 120 as shown in Figure 2 and at the same time in the process of sealing and coupling the container cover 120 to the upper surface of the container body 110 It may be configured to be injected into the test chamber (C). That is, the container cover 120 and the BOP equipment 200 are mutually coupled so as to be integrally transported, and the container cover 120 is moved by moving the container cover 120 and the BOP equipment 200 downward by the riser 220. Sealed and coupled to the container body 110 and at the same time the BOP equipment 200 can be configured to be introduced into the test chamber (C). In addition, the BOP equipment 200 may be configured to be seated and coupled to the test well head 300 located at the bottom of the inner space of the container body 110 at the same time it is introduced into the test chamber (C). Therefore, the operation of sealing the container cover 120 to the container body 110, the operation of the input of the BOP equipment 200 and the coupling work with the test wellhead 300 can be performed at the same time, through which the operation is simplified and convenient Can be performed quickly.

In this case, in the process of injecting the BOP equipment 200 together with the container cover 120 into the internal space of the pressure vessel 100, the pressure vessel 100 of the pressure vessel 100 to guide the vertical movement path of the BOP equipment 200 As shown in FIG. 2, a separate movement guide part 130 may be mounted in the internal space.

In addition, the test wellhead 300 may be disposed in a form supported by a separate wellhead support 310 as shown in FIG. 2, and the wellhead support 310 raises the test wellhead 300. It may be configured in the form of a cylinder or an elastic spring that is hydraulically actuated to support it. Therefore, as shown in FIG. 2A, the test wellhead 300 is moved upward by the wellhead support 310 when the BOP device 200 is not seated on the test wellhead 300. As shown in FIG. 2B, the test wellhead 300 is wellheaded as the BOP equipment 200 is introduced into the pressure vessel 100 and seated in the test wellhead 300. It is moved downward in a state supported by (310). According to this structure, the coupling process between the BOP device 200 and the test wellhead 300 may be made more accurately and stably.

Looking at the relationship between the container cover 120, riser 220 and the BOP device 200 in more detail, the upper surface of the container cover 120, the riser 220 is coupled, the lower surface of the container cover 120 The BOP equipment 200 is coupled, the riser 220 and the BOP equipment 200 may be coupled to be connected to each other via the container cover 120.

First, the riser 220 is a main pipe 220-3 in the form of a pipe so that the drill string, etc. can pass through the inner space as shown in Figure 3, the main for the operation and mud circulation of the BOP equipment 200 It is configured to include a plurality of sub-pipes (220-1) disposed around the outer periphery of the pipe (220-1). The plurality of sub pipes 220-1 includes two hydraulic lines for operating the BOP equipment 200 and three mud circulation lines for mud circulation. Outside the riser 220, a separate auxiliary hydraulic hot line and a sub line 221 such as a mux cable for electrical operation of the BOP device 200 are disposed.

The BOP equipment 200 has a connecting portion 201 for connecting to the riser 220 at the upper end, and the connecting portion 201 is connected to the main tube 220-3 of the main tube 220-3 of the riser 220. 1) and the sub pipe connection part 201-2 connected to the sub pipe 220-1 of the riser 220. The sub pipe connection 201-2 is connected to two hydraulic lines for operating the ram, the annular and various valves of the BOP equipment 200, and three mud circulation lines for mud circulation. In addition, separate sub-operating lines 202 such as auxiliary hydraulic lines and mux cables are provided.

A riser connection port 121 is formed on the upper surface of the container cover 120 so that the riser 220 is detachably coupled. The riser connection port 121 includes a main pipe connection port 121-1 and a sub pipe connection port. (121-2). The flanger connection part 220-2 of the riser 220 may be coupled to the main pipe connection port 121-1 by a bolting coupling or a fitting method through a separate coupling bolt (not shown), and the sub pipe connection port. A plurality of sub pipes 220-1 may be coupled to the 121-2 so as to be inserted and separated in a fitting manner.

In addition, a sub line connection port 122 is formed on the upper surface of the container cover 120 to be connected to a sub line, and a plurality of sub lines 221 are inserted into and removed from the sub line connection port 122 in a fitting manner. May be combined as much as possible.

BOP connection port 123 is formed on the lower surface of the container cover 120 to be detachably coupled to the BOP equipment 200, the BOP connection port 123 is the main pipe connection 201-1 of the BOP equipment 200 And the sub pipe connecting portion 201-2 are formed to be detachably coupled to each other by a fitting method or a bolting method using a coupling bolt, and includes a main BOP connecting port 123-1 and a sub BOP connecting port 123-2. do.

In addition, a plurality of BOP line connection ports 124 may be formed on the bottom surface of the container cover 120 such that the plurality of sub operation lines 202 are detachably coupled to each other.

Through this configuration, the riser 220 and the sub line 221 are detachably coupled to the upper surface of the container cover 120, and the BOP equipment 200 and the sub operation line 202 are attached to the lower surface of the container cover 120. Removably coupled. In this case, the riser 220 and the BOP equipment 200 are communicated with each other through the riser connection port 121 and the BOP connection port 123 as shown in FIG. 4, and the sub line 221 and the sub operation line 202. ) Are communicated with each other via the sub line connection port 122 and the BOP line connection port 124.

Meanwhile, in the drilling facility 210, a separate control room that controls the operation of the BOP equipment 200, the external pressure supply unit 400, and the internal pressure supply unit 500, and simultaneously monitors the operation state of the BOP equipment 200. 600 may be provided. The control room 600 may be connected to the BOP equipment 200 and the pressure vessel 100 through the riser 220, and may be connected to the external pressure supply unit 400 and the internal pressure supply unit 500 through separate cable lines. have. In this case, the control room 600 may be disposed in the drilling facility 210, but may be disposed in various places such as a separate offshore structure or a land adjacent to the sea.

In order to control the BOP equipment 200 in the control room 600, two mux cables for supplying electrical signals are connected from the control room to the BOP equipment, and the BOP from a hydraulic supply device such as a HPU (Hydraulic Power Unit) It is configured to supply hydraulic pressure to the BOP equipment through two hydraulic lines (conduit line) provided in the equipment. That is, power and valve operation signals are transmitted through the mux cable, and the ram and the ennulas of the BOP equipment are closed and opened using the supplied hydraulic pressure.

According to the structure as described above, in addition to the external pressure and internal pressure test for the BOP equipment 200 can be tested whether the installation process of the BOP equipment 200 is normally performed. For example, it may be tested whether the BOP equipment 200 latches normally to the test wellhead 300. In addition, through the control room 600 that can control the operation of the BOP equipment 200, it is possible to test various control tests for the BOP equipment 200 and all the operations occurring in the actual subsea well.

At this time, the inside of the pressure vessel 100 may be additionally equipped with a variety of sensors and video equipment, such as to monitor the internal state of the pressure vessel 100 and the operating state of the BOP equipment 200, such sensors and images Equipment may be connected to the control room 600 to monitor the operating status of the BOP equipment 200 through the control room 600.

For example, an underwater camera 150 and an illumination (not shown) may be mounted inside the pressure vessel 100 to observe the internal condition of the pressure vessel 100 as shown in FIG. The sensor module 140 may be mounted inside the pressure vessel 100 to measure the internal state of the 100. The sensor module 140 may include a pressure sensor, a temperature sensor, a strain gauge, a level gauge, and the like. The strain gauge can measure the amount of deformation of the ram device of the BOP equipment 200, and the environmental conditions such as pressure and temperature of the internal space of the pressure vessel 100 can be measured by the pressure sensor and the temperature sensor. . In addition, it is possible to observe the latching coupling process of the BOP equipment and the test wellhead through the underwater camera 150, it can be confirmed whether the equipment is damaged or the like.

Meanwhile, as illustrated in FIG. 2, the pressure controller 100 may be equipped with an acoustic controller 160 that transmits and receives information to and from the control room 600. The acoustic controller 160 may include an acoustic control command unit, a transducer, It consists of a transceiver and the like. The acoustic control command unit may perform an operation control function of the BOP equipment, and the BOP equipment control information may be received and the monitoring information may be transmitted through the transducer and the transceiver.

Meanwhile, a separate robot arm 700 may be mounted in the pressure vessel 100 to enable a test assistance operation for the BOP device 200 fixedly mounted in the test chamber C. The robot arm 700 may be manufactured in various forms, and a robot arm used in a general remotely operated vehicle (ROV) may be applied. The robot arm 700 may be configured to assist the coupling process between the BOP device 200 and the test wellhead 300 or to perform various tasks such as an operation test function, a pressure test assistant function, and a maintenance function for the BOP device. The operation control may be performed through the control room 600.

In addition, the guide rail 710 is mounted on the inner surface of the pressure vessel 100 to move the position of the robot arm 700, the robot arm 700 may be coupled to move along the guide rail 710. . At this time, the guide rail 710 may be formed long in the vertical direction on the inner side of the pressure vessel 100, as shown in Figure 1, in addition to the long side in the circumferential direction on the inner side of the pressure vessel 100 It may be formed in various forms such as.

In the above description, only the BOP device 200 is described as a test target device, but in addition to the BOP device 200, various drilling equipments used in a deep sea environment such as a Christmas tree may be applied, and the mud may be extended by applying various drilling equipments. Integrated operational tests, including transfer and mud cycling testing and Christmas tree equipment testing, will also be available. Here, the integrated operation test may include all system operations from departure to return after performing the mission. In addition, the equipment under test can be applied not only to drilling equipment but also all kinds of equipments working or installed in the deep sea, and the external pressure test and the internal pressure test on them can be performed.

5 is an operation flowchart schematically showing the configuration of a drilling rig test method according to an embodiment of the present invention.

The present invention provides a drilling rig test method using the drilling rig test apparatus described in Figures 1 to 4, this drilling rig test method can be performed in the manner described above, it will be briefly described here.

Drilling equipment test method according to an embodiment of the present invention, the step (S1) for placing the pressure vessel 100, the test chamber (C) formed therein on the seabed, and the liquid (L) in the test chamber (C) Storing (S2), putting the test target equipment to be immersed in the liquid (L) stored in the test chamber (C) (S3), and the pressure of the liquid (L) stored in the test chamber (C) is severe And increasing the pressure of the liquid through the external pressure supply unit 400 to reach the pressure (S4).

At this time, the pressure vessel 100, the test chamber (C) is formed therein, the container body 110 is formed in the form of the upper surface is opened, the container cover that is sealingly coupled to the open upper surface of the container body (110) Separately formed by the 120, the test target equipment is coupled to the bottom of the container cover 120 is configured to be injected into the test chamber (C) in the process of the container cover 120 is coupled to the container body (110).

The test target equipment is applied to the BOP equipment 200 as described above, and the test well head 300 is fixedly mounted so that the BOP equipment 200 is seated and coupled under the inner space of the pressure vessel 100. At this time, the drilling equipment test method according to an embodiment of the present invention, the test wellhead 300 through a separate internal pressure supply unit 500 so that the internal pressure is transmitted to the BOP equipment 200 through the test wellhead 300. It is configured to further comprise the step (S5) of supplying a high pressure fluid.

The vessel cover 120 of the pressure vessel 100 is connected to the lower end of the riser 220 extending to the seabed from a separate drilling facility 210 disposed on the sea, moved downward with the riser 220 to move the vessel body ( Coupled to 110, the BOP equipment 200 is configured to be connected to the riser 220 through the container cover 120. In this case, as the container cover 120 is coupled to the container body 110, the BOP device 200 is preferably configured to be seated and coupled to the test wellhead 300.

Through this process, the external pressure test and the internal pressure test of the BOP device 200 may be performed, and the combined test in which the BOP device 200 is coupled to the test wellhead 300 may also be performed. Monitoring may be performed through a separate control room 600. In addition, the equipment under test can be extended to a variety of deep sea equipment used in the deep sea to perform integrated operational tests including mud transfer and mud circulation testing and Christmas tree equipment testing.

The above description is merely illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention pertains may make various modifications and changes without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of the present invention.

100: pressure vessel 110: vessel body
111: external pressure supply port 112: internal pressure supply port
120: container cover 121: riser connection port
122: sub line connection port 123: BOP connection port
124: BOP line connection port 130: moving guide portion
140: sensor module 150: underwater camera
160: acoustic control unit 200: BOP equipment
201: Connection 202: Sub operation line
210: drilling rig 220: riser
300: test well head 400: external pressure supply unit
500: pressure supply unit 600: control room
700: robot arm 710: guide rail

Claims (19)

In the drilling equipment test apparatus for testing drilling equipment used in a deep sea environment,
A test chamber is formed therein to allow the test target equipment to be inserted into the test chamber, and the test chamber includes a pressure container configured to store a liquid to lock the test target equipment; And
External pressure supply unit for raising the pressure of the liquid so that the pressure of the liquid stored in the test chamber reaches a deep sea pressure
Including, the pressure vessel is
The test chamber is formed therein and is formed separately from the container body is formed in an open top surface, and a container cover sealingly coupled to the open upper surface of the container body,
The test target equipment is coupled to the lower end of the container cover is put into the test chamber in the process of the container cover is coupled to the container body,
The test target equipment is a BOP equipment,
A test wellhead is fixedly mounted on the inner bottom of the container body so that the BOP device can be coupled, and the test wellhead is coupled to the test wellhead as the container cover is hermetically coupled to the container body. Drilling equipment test apparatus, characterized in that arranged to. The method of claim 1,
The pressure vessel is disposed on the seabed, and the drilling apparatus test apparatus, characterized in that the seawater is stored in the test chamber of the vessel body with the vessel cover open. delete delete The method of claim 1,
And an internal pressure supply unit for supplying a high pressure fluid to the test wellhead such that the internal pressure is transmitted to the BOP equipment through the test wellhead. The method according to any one of claims 1 to 2 and 5,
Drilling equipment test apparatus, characterized in that the robot arm is mounted to the inside of the pressure vessel to enable the test assistant operation for the test target equipment fixed to the test chamber. The method of claim 6,
A guide rail is mounted on an inner side of the pressure vessel, and the robot arm is coupled to the guide rail so as to be movable. The method of claim 1,
The vessel cover is connected to the bottom of the riser extending to the seabed from a separate drilling facility disposed on the sea, drilling equipment test apparatus, characterized in that coupled to the vessel body to move down with the riser. The method of claim 8,
Drilling equipment test apparatus, characterized in that the riser connection port is formed on the top of the container cover to be detachably coupled, the riser and the BOP equipment is interconnected through the riser connection port. The method of claim 9,
BOP connection port is formed at the bottom of the container cover to be detachably coupled to the BOP equipment, the riser and the BOP equipment is a drilling equipment test device, characterized in that interconnected through the BOP connection port and riser connection port . The method of claim 8,
A sub line connection port is formed at a top of the container cover to detachably couple a separate sub line disposed around the outer circumference of the riser, and an operation line mounted on the BOP device is connected to the sub line through the sub line connection port. Drilling rig test device, characterized in that connected to the line. The method of claim 11,
A lower end of the container cover is formed with a BOP line connection port to be detachably coupled to the operation line of the BOP equipment, the operation line of the BOP equipment is connected to the sub line through the BOP line connection port and the sub line connection port Drilling equipment test apparatus, characterized in that. The method of claim 5,
Drilling equipment test apparatus further comprises a separate control room for controlling the operation of the BOP equipment, the external pressure supply unit and the internal pressure supply unit and monitor the operating state of the BOP equipment. The method of claim 5,
Drilling equipment test apparatus, characterized in that the pressure vessel is connected to a negative power source to prevent corrosion. In the drilling equipment test method for testing drilling equipment used in a deep sea environment,
Disposing a pressure vessel on the seabed, in which a test chamber is formed;
Storing liquid in the test chamber;
Introducing a device under test to be immersed in the liquid stored in the test chamber; And
Raising the pressure of the liquid through the external pressure supply unit such that the pressure of the liquid stored in the test chamber reaches a deep sea pressure;
Including, the pressure vessel is
The test chamber is formed therein and is separated into a container body having an upper surface formed in an open shape, and a container cover sealingly coupled to an open upper surface of the container body, wherein the container cover is opened in the test chamber. Seawater is stored,
The test target equipment is coupled to the lower end of the container cover is put into the test chamber in the process of the container cover is coupled to the container body,
The test target device is applied as a BOP device, and a test well head is fixedly mounted on the inner bottom of the container body so that the BOP device can be coupled, and the test well head is sealingly coupled to the container body. According to claim 1, wherein the BOP equipment is arranged to be coupled to the test wellhead. delete The method of claim 15,
And supplying a high pressure fluid to the test wellhead through a separate internal pressure supply unit such that the internal pressure is transmitted to the BOP equipment through the test wellhead. The method of claim 17,
It is provided with a separate control room for controlling the operation of the BOP equipment, external pressure supply unit and internal pressure supply unit and monitor the operating state of the BOP equipment,
Drilling equipment test method, characterized in that for performing an integrated operation test including a coupling test, the external pressure test and the internal pressure test for the BOP equipment coupled to the test wellhead through the control room. The method of claim 15,
The vessel cover is connected to the lower end of the riser extending to the seabed from a separate drilling facility disposed on the sea, moving downward with the riser and coupled to the vessel body, the BOP equipment is connected to the riser through the vessel cover Drilling equipment test method, characterized in that connected.

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