KR20150031412A - An apparatus, system and method for actuating downhole tools in subsea drilling operations - Google Patents

Abstract

A downward ballistic logging tool for analyzing a portion of an underwater borehole in a subsea drilling operation and a method of using the same are provided. The downward ballistic logging tool preferably has an underwater chassis incorporating a sensor and power system including at least a conductive sensor and a magnetic sensitive sensor for analyzing the walls of the borehole. If the downward ballistic logging tool is not located in a designated portion of the undersea drilling rig of the undersea drilling operation (e.g., when the tool is being used across a borehole), it is automatically operated, preferably magnetically operated A switch will provide power to the sensor from the power system and will remove power if the downlink ballistic tool is located at a designated portion of the undersea drilling rig (e.g., when a downhole tool is not in use).

Description

[0001] APPARATUS, SYSTEM AND METHOD FOR ACUTE DOWNHOLE TOOLS IN SUBSEA DRILLING OPERATIONS [0002]

The present invention relates to an apparatus, system, and method for deploying and operating a downhole logging tool from a subsea drilling rig. In particular, the present invention relates to, but is not limited to, automatically operating an undersea downhole logging tool that can be used to determine the petrological character of the downhole.

Note that references to background technology should not be construed as acknowledging that such technology has a common general knowledge in Australia or elsewhere.

In particular, subsea drilling in fairly deep water (eg, 1,000 m to 3,000 m +) is relatively complex, time consuming, and costly to operate. BACKGROUND OF THE INVENTION Remote-operated undersea systems that are connected to a surface vehicle or platform by an "umbilical" line in general and have underwater drilling rigs are known for use in such drilling operations. Subsea drilling rigs generally include a frame that provides support for various elements, such as a drill head support structure that typically includes a drill string that can pierce the borehole in the seabed.

One aspect of subsea drilling that is perceived as particularly troublesome is to determine the petrological characteristics of subsea sediments. Typically, petrological properties are determined by obtaining and analyzing core samples by drilling. Typically, a core barrel at the end of the drill string is used to obtain a core sample.

However, when the core barrel is filled, the core sample must be recovered from the core barrel. Generally, this involves collecting the entire drill string each time the core sample is withdrawn. Due to the time and expense of recovering core samples in this manner, core drilling becomes impractical at deep holes.

For example, efforts have been made to provide a storage area for drill rods and core barrels, and to provide a process for exchanging core barrels filled in drills with empty core barrels to solve the above problems. Thus, for a deeper hole, multiple core samples can be obtained without retrieving the entire drill string to obtain each core sample. The process is faster, but still complex, time consuming, and costly. Also, if the core sample is lost (e.g., broken, damaged or even physically lost), the petrological character of at least a portion of the borehole becomes unclear.

Another problem with core samples is that in general, the core sample can only be recovered and analyzed to know the petrological properties of the borehole. Because of this, the time delay can be significant and it becomes substantially ineffective in understanding the characteristics of the borehole. As a consequence of the time delay, it is often the case that the borehole penetrates past the optimum "hole end" (EOH) depth during drilling operations. As a result, drilling time and resources are wasted.

A downward ball logging tool that descends into the borehole and analyzes the petrological characteristics of the borehole is considered. It is desirable to be able to turn the downward ballistic logging tool on and off so that the downward ballistic logging tool does not continue to operate. If the downward ballistic logging tool continues to operate, it may not only increase power usage, but it may also cause interference. The increase in power usage is particularly problematic for battery powered downstream logging tools that need to be recovered to the surface for battery recharging.

It is considered impractical to provide a power switch that is physically powered by a tool located on the seafloor. Not only are the moving parts undesirable at such depths, but also having a means for operating the switch remotely can be problematic. For example, a robot arm may be provided in the drilling rig to operate the switch, but this increases the cost and complexity of the drilling rig. Also, if the operator forgets to operate the switch before and after use, considerable resources may be wasted.

It is an object of the present invention to provide an apparatus, system and method for deploying and operating a downward ballistic logging tool from a submarine drill rig assembly, the apparatus, system and method for overcoming or improving at least one of the problems described above, , A system and a method.

Other preferred objects of the present invention will be apparent from the following description.

According to a first aspect of the present invention there is provided a downhole logging tool for use in an undersea borehole of a subsea drilling operation,

An underwater chassis including an electronic component including a sensor and a power system; And

And an automatic operation switch that selectively provides power to the electronic component from the power system,

Wherein the sensor includes at least a conductive sensor and a magnetic sensitive sensor, and when the downward ballistic logging tool is located at a designated portion of a submarine drilling rig of a subsea drilling operation, the automatic operation switch is actuated to remove power from the electronic component And will also provide power to the electronic component if the downward ballistic logging tool is not located at a designated portion of the submarine drilling rig.

The autonomous switch preferably comprises a magnetic switch operative when in proximity to a magnetic field source. The top field source is preferably located at a designated portion of the underwater drilling rig. More preferably, the magnetic field source is located adjacent to the downward ballistic tool storage rack of the drilling rig.

Preferably, the magnetic switch is normally open and closed by the magnetic field of the magnetic field generator. Preferably, the magnetic switch is a reed sensor. Preferably, the lead sensor is part of an autonomous switch circuit comprising at least one transistor. Advantageously, the transistor is electrically connected to a power source and the lead sensor switches the transistor to selectively provide power to the electronic component.

Preferably, the electronic component includes a data delivery system in communication with the sensor. Preferably, the sensor comprises a radial measurement sensor, or sensor, for performing a measurement on a wall of the borehole.

The sensor of the downward ballistic logging tool further comprises a temperature sensor, a resistance sensor and / or a natural gamma sensor. Preferably, the resistance sensor is an inductive conductive sensor, which may be a dual coil inductive conductive sensor, a coil-focused inductive conductive sensor, or other type of inductive conductive sensor. Preferably, a natural gamma sensor is used for depth association.

Advantageously, said submersible chassis comprises an engaging portion detachably secured to a corresponding engaging portion of a submarine drilling rig. Preferably, the underwater chassis incorporates a sensor, a data delivery system and a power system. The automatic operation switch is preferably located in a downward ballistic tool that includes a battery in the power system.

The data delivery system may include a data store for storing data received from the sensors. This data delivery system can store data for delivery on demand.

The downbound ball logging tool may further include a processor. The processor preferably communicates with sensors, data delivery systems and / or power systems. The processor can process the raw data given from the sensor. The data delivery system preferably communicates with the sensor via the processor, and preferably also receives processed sensor data from the processor.

The power system preferably includes a battery. The power system may also include a power delivery system. The battery may comprise a plurality of small batteries. The power delivery system preferably delivers power from an external power source, such as the power portion of the drilling rig in a subsea drilling operation.

The battery may be rechargeable and the power system may further comprise a battery charging system. The battery charging system can charge the battery from the power delivery system or inductively. The battery charging system can also be operated by an automatic operation switch. Alternatively, once the battery charging system is detected, preferably the automatic operation switch can be actuated if an inductive charging station is detected.

Preferably, the engagement of the downward ballistic tool secures the downward ballistic logging tool to the wireline system or drill string. When the coupling portion of the downward ballistic logging tool is secured to the wireline system, the coupling portion preferably includes a latch head. When the coupling part of the downward ballistic logging tool is fixed to the drill string, the coupling part preferably comprises an adapter. The adapter preferably connects the downward ballistic logging tool as a bottom ball assembly of the drill string. The downward ballistic logging tool may have a coupling for coupling to the wireline system and a coupling for coupling to the drill string.

The wireline system preferably lowers the downward ballistic logging tool through its drill string when the drill string is in the borehole at the full depth and unloads the logging tool, preferably a portion of the drill string, Can be used for latching. Preferably, at least the sensor portion of the downward ballistic tool projects from the bottom of the drill string. In this case, the drill string is generally recovered from the borehole to a submarine drill rig, which records data about the borehole wall of the borehole from the sensor as it is elevated with the drill string.

Preferably, the underwater chassis has a length of less than 6 m and an outer diameter of less than 150 mm. More preferably, the underwater chassis has a length of less than 3 m and an outer diameter of less than 75 mm. Embodiments of the invention preferably have a length of less than 2 m and an outer diameter of less than 50 mm.

According to a second aspect of the present invention, there is provided a submarine drilling rig including the aforementioned downward ballistic logging tool.

According to a third aspect of the present invention, there is provided a system for using downbound logging tools in a subsea drilling operation,

Includes a downward ballistic logging tool including a power system, a sensor, and an autonomous operation switch across the borehole,

Wherein the sensor includes at least a conductive sensor and a magnetic sensitive sensor, the automatic operation switch selectively providing power from the power system to a sensor of a downbound ballistic tool,

The automatic operation switch activates the downward ballistic logging tool when the downward ballistic logging tool leaves a designated portion of the undersea drilling rig and also deactivates the downward ballistic logging tool when the downward ballistic logging tool enters a designated portion of the undersea drilling rig .

According to a fourth aspect of the present invention there is provided a method of using a downbound logging tool in a subsea drilling operation,

Selecting a downward ballistic logging tool to traverse the seabed borehole;

Moving the selected downward ballistic logging tool from a designated portion of the submarine drilling rig; And

When the downward ballistic logging tool leaves the designated portion of the drilling rig and activates the downward ballistic logging tool and the downward ballistic logging tool enters the designated portion of the undersea drilling rig, And automatically activating the automatic operation switch of the switch.

The method using a downward ballistic logging tool,

Connecting the downward ball logging tool to the wire line;

Lowering the downward ball logging tool through the drill string into the submarine borehole;

Placing the downward ballistic logging tool in the receiving portion of the lowermost drill string;

Separating and retracting the wire line; And

And performing a measurement with a downward tool when the drill string is removed from the borehole.

Advantageously, said downward ballistic tool performs a radial direction measurement on the wall of the borehole. Advantageously, said downward ballistic tool comprises at least a conductive sensor and a magnetic sensitive sensor. Preferably, the downward ballistic logging tool in the system and method utilizing a downward ballistic logging tool in a subsea drilling operation is a downward ballistic logging tool as described above.

Preferably, the downward ballistic logging tool is secured to and separated from the undersea drilling rig of the undersea drilling operation by a remote actuation mechanism. Preferably, the remote operating mechanism is operated from a surface vehicle or platform.

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

Figure 1 schematically depicts a subsea drilling operation device comprising a drill string positioned in a borehole.
Figure 2 schematically shows a subsea drilling rig using a submersible wireline winch to lower the downward ballistic tool into the borehole.
Figure 3a schematically illustrates a downward ballistic tool that is lowered into a drill string.
Figure 3b schematically shows the down-borrowing tool of Figure 3a located in the bottom ball assembly of the drill string.
4 is a side view of a portion of a submarine drilling rig including a downward ballistic tool storage area;
5 shows an electronic circuit diagram for an automatic operation switch.
Figure 6 is a side view of the downward ballistic logging tool.

Figure 1 schematically depicts a subsea drilling operation device 10 located on a seabed 12 below sea level 14. [ The seabed drilling apparatus 10 may be positioned at various lengths below the sea surface 14 but generally the seabed 12 is at least 1000 m below the sea surface 14 and in many cases below the sea surface 14 It is 3000 m.

The undersea drilling apparatus 10 has a submarine drilling rig 16 connected to a surface vehicle or platform 18 by an "umbilical" cable 20. The umbilical cable 20 Control and telemetry to undersea drilling rig 16. Generally drilling rig 16 is powered remotely from a surface vehicle or platform 18 via an umbilical cable 20 Although the surface vehicle or flat 18 is shown as being located on sea level 14, it will be appreciated that the surface vehicle or platform may also be located elsewhere, such as land.

The undersea drilling rig 16 has a drill head assembly 22 connected to a drill string 24 in a borehole 26. During the drilling operation, the drill head assembly 22 controls the drill string 24 to pierce the borehole 26. A typical drill string 24 has a conduit that delivers drilling fluid to a drill bit (not shown) of a bottom hole assembly at the distal end 24 'of the drill string 24. A downward ballistic logging tool 100 (not shown in FIG. 1) (to be described in more detail with respect to FIG. 6) to determine the petrological characteristics of the subsea sediments adjacent to the wall of the borehole 26, Can be fixed to the distal end 24 'of the drill string 24.

FIG. 2 illustrates an alternative method for inserting the downward ballistic logging tool 100 into the borehole 26. Instead of fixing the downward ballistic logging tool 100 as a bottom ball assembly of a drill string 24, the downward ballistic logging tool 100 may include a wire line (not shown) that can be raised and lowered by a submersible wire line winch 30, (Not shown). Electrical connection between the wire line 28 and another part of the drilling rig 16 (e.g., the umbilical cable 20) may be provided by the electrical slip ring 32. [ Alternatively, the wire line may be purely mechanical and used only to raise and lower the downbound ball logging tool 100 in the borehole 26.

3A-3C illustrate another method for inserting the downward ballistic logging tool 100 into the borehole 26. FIG. 3A, the downward ballistic logging tool 100 is connected to the wire line 28 via the engagement portion 112 and is lowered into the borehole 26 by the wire line winch 30. As shown in Fig. The wye line winch 30 descends the downward ballistic logging tool 100 through the interior of the plurality of drill rods 24 " constituting the drill string 24. The three drill rods 24a, 24b and 24c are shown wherein the drill rod 24a is the uppermost drill rod 24 "and is received in the drill rod foot clamp 34, the drill rod 24b is the intermediate drill rod 24" The drill rod 24c is the lowermost drill rod 24 "and the distal end 24 'of the drill string 24 has a receptacle 36 for receiving the downward ballistic tool 100.

FIG. 3B shows the downward ballistic tool 100 in the lowered position, wherein the downward ballistic tool is received in the receiving portion 36 of the lower drill rod 24c. The wire line connector 28 'at the end of the wire line 28 is separated from the engaging portion 112 of the downward ballistic logging tool 100 and the wire line winch 30 moves the wire line 28 into the drill string 24). The downward ballistic logging tool 100 is seated in the receiving portion 36 of the lowermost drill rod 24c in a state in which most of the sensors including the sensor are protruded from the end of the downward hollow string 24. Thus, the sensor in the downward ballistic logging tool 100 is enabled to make measurements on the wall of the borehole 26 without interference or interference of the drill string 24.

3C shows that the wire line winch 30 pulls the wire line 28 completely out of the drill string 24 and the drill string 24 is removed from the borehole 26. As the drill string 24 rises, the individual drill rod 24 "is removed from the string for storage. As shown in Figure 3c, the uppermost drill rod 24a is already removed from the drill string, The downstream ballistic tool 100 is in an operative state and makes a radial measurement of the wall of the borehole 25. During drilling of the drill string 24, 26, the downward ballistic logging tool 100 can be retrieved, and the sensor data can be downloaded at the appropriate time.

A portion of the undersea drilling rig 16 is shown in FIG. 4, wherein the designated storage of the drilling rig 16 is shown in the form of a downward ballistic tool storage rack 200. 4 also shows the drill head 22 with the spindle 202. [ There is provided a tool arm 204 that allows a tool, such as a downward ballistic logging tool, to be moved from the rack 200 onto a drill string 24 (attached to the spindle 202). The drill head 22 can be moved vertically with a controllable speed and force to control the logging tool and drill string 24 within the borehole 26. The tool arm 204 may also be used to move the downward ballistic logging tool 100 to a position for engagement with the wire line 30. [

As will be described in greater detail with respect to FIG. 6, the downward ballistic logging tool 100 is powered by a battery and has a switch 152. The switch 152 is an automatic operation switch. The automatic action switch 152 of the downward ballistic logging tool 100 is disabled (i.e., substantially not powered) when the downward ballistic logging tool 100 is stored in the tool rack 200 And is activated to be activated when it is removed from the rack 200.

In a preferred embodiment, when the downward ballistic logging tool 100 is positioned in the tool rack 200, the automatic operation switch is located adjacent to the tool rack 200, Magnetically by a magnet 206 disposed immediately adjacent to the position. If the switch 152 is near the magnet adjacent to the tool rack 200, the switch 152 is activated to automatically deactivate the tool 100.

The downward ballistic logging tool can be charged while in the tool rack 200. An inductive charging device (not shown) may be provided on or adjacent to the tool rack 200. Using the power given in the subsea drilling rig 16, the inductive charging device generates an electromagnetic field through the induction coil. If the downward ballistic logging tool 100 is near the inductive charging device, a second inductive coil in or at least electrically connected to the battery of the downcomer tool 100 converts the electromagnetic field into electrical charge to charge the battery do. As an alternative to the magnetic switch, detection of the inductive charge field may be used instead to activate the automatic operation switch.

Fig. 5 shows a preferred auto-actuated switch circuit diagram 500. Fig. Circuit 500 includes four resistors R1, R2, R3 and R4, a reed switch 510 and two transistors 512 and 514 in the form of a MOSFET. The reed switch 510 is normally open and closes when it receives a magnetic field by a magnet 206 adjacent the tool rack 200. The circuit 500 is directly connected to a power source in the form of an 18-cell battery pack 502.

Typically, the reed switch allows a limited amount of current (eg, 0.1A) to flow. The circuit 500 allows the reed switch 510 (with a good sensitivity to the magnetic field) to be used without inappropriately limiting the current drawn from the battery pack 502. In a preferred embodiment, when the reed switch 510 is open, the circuit 500 allows a current of approximately 7.5 A to flow.

In a preferred embodiment, when the reed switch 510 is open, i.e., the switch does not receive a magnetic field, V _in and V _out The measured resistance is 0.0226 Ω to 0.028 Ω. When the reed switch 510 is closed, that is, when the switch receives a magnetic field, V _in and V _out The measured resistance between 4.8 MΩ and 24 MΩ. As a result of this high resistance when the reed switch 510 is closed, a minimum current flows through V _out if current is present.

FIG. 6 shows a preferred downward ballistic logging tool 100. The downward ballistic logging tool 100 has an underwater chassis 110 in the form of a high pressure housing that is shaped to traverse the borehole 26. The chassis 110 has an engagement portion 112 and includes one or more sensors, a data delivery system in communication with the sensors, and a power system that provides power to the sensors and data delivery system. Specifically, the downward ballistic logging tool 100 includes a battery pack 150, a power switch 152, an electronic device portion 170, a natural gamma sensor 172, a conductive sensor 174, a magnetic sensitive sensor 176, , And an external temperature sensor (178). The electronic device unit 170 includes a processor and a data storage memory.

The coupling portion 112 of the downward ballistic logging tool 100 may be coupled to both the drill string 24 and the wire line 28. Thus, the downward ballistic logging tool 100 may perform measurements across the borehole 26 using any of the methods described with respect to Figures 1,2 or 3a-3c. Most preferably, the downward ballistic logging tool 100 is used in the method described with respect to FIGS. 3A-3C, wherein the downward ballistic logging tool 100 uses a wire line 28, Descends and rises with the drill string 24 while performing measurements on the wall of the borehole 26.

Prior to use, the downward ballistic logging tool 100 is located in the tool storage rack 200 of the drilling rig 12. The auto-action switch 152 is kept open by one or more magnets adjacent the tool rack 200 (i.e., the reed switch in circuit 500 is closed and the downward ballistic tool 100 is turned off) , Preserve power). When the downward ballistic logging tool 100 is desired to be used, the downward ballistic logging tool 100 is selected and removed from the tool rack 200. As the downward ballistic logging tool 100 is removed from the rack, the switch 152 is removed from the magnetic field adjacent to the tool rack 200 and the switch 152 is automatically activated to the loading position (i.e., the circuit 500 The reed switch is open and the downward ballistic logging tool 100 is on). And the downward ballistic logging tool is automatically activated by the switch 152 for use in the borehole 26.

The automatically activated downward ballistic logging tool 100 can then be lowered into the borehole 26 to provide measurements that can be used to determine the petrological properties of the subsea sediments.

When the downward ballistic logging tool 100 is connected to a drill string 24 as shown in FIG. 1, the tool arm 204 is moved downward to allow the downward ballistic logging tool 100 to deploy as a bottom ball assembly. The coupling portion 112 of the logging tool 100 is connected to the distal end 24 'of the drill string 24. When the downward ballistic logging tool 100 is connected to the wire line 28 (as shown in FIGS. 2 and 3), the wireline winch 30 is positioned above the borehole 26 and the downward ballistic logging tool 100 Is lowered below the borehole 26.

When the downward ballistic logging tool 100 wishes to be seated in the receiving portion 36 of the drill string 24 as shown in Figures 3A-3C, the wireline winch 36 is pulled out of the downward ballistic tool 100, Descends into the receiving portion 36 and separates from the engaging portion 112 of the downward ballistic logging tool 100 to retract the wire line 28 into the drill string 24 foil. The downward ballistic logging tool 100 then moves up along the borehole 26 during a normal drill string retrieval operation to perform measurements and record data. Once the lowermost drill rod 24c is positioned in the drill rod foot clamp 34, it can be connected to the downward ballistic tool 100 using the wire line 28 and returned to the tool storage area 200 In which the power supply to the downward ballistic logging tool 100 is automatically interrupted by the automatic actuation switch 152 in the presence of the magnetic field of the magnet 206. [

The sensors of the down-ball logging tool 100 measure the characteristics of the walls of the borehole 26 and typically send data to the data delivery system via the processor. The data delivery system stores the data for later delivery (e.g., when called). The data of the sensor provides a geophysical property of the downward hole, which can be used to determine the petrological properties of the analyzed part of the borehole.

Data from magnetic sensitive sensors can be used to determine the area of many sulfides in the seabed and non-mineralized lower volcanic rocks. The magnetic susceptibility of the altered volcanic rocks and sulphides is damaged by high temperatures, so magnetic susceptibility can be used to discriminate the area of interest and to determine the "end of the hole" when reaching a non-mineralized lower volcanic rock.

The downward ballistic logging tool 100 of FIG. 6 does not have dedicated power or communication lines connected to the drilling rig 16. Therefore, the downward ballistic logging tool is powered by a rechargeable battery, which can be inductively recharged when stored in drilling rig 16. Alternatively, the downward ballistic logging tool 100 may be charged at the surface. Generally, the down-ball logging tool 100 locally stores the data in on-board memory, while the down-ball logging tool uses conventional data transfer techniques such as acoustic transfer, or can transfer data over the umbilical cable have.

When finished with the downward ballistic logging tool 100, the tool is retracted from the borehole 26 and repositioned in the tool rack 200 of the drilling rig 12. When the tool is repositioned in the tool rack, the presence of a magnetic field generated in the magnet 206 adjacent to the tool rack 200 opens the auto-actuated switch 152 (i.e., The switch 510 is closed). This process allows the downward ballistic logging tool 100 to be automatically deactivated to conserve battery power and prevent interference that may be caused by the downward ballistic logging tool.

Advantageously, the downward ballistic logging tool 100 can quickly and relatively easily perform a petrological analysis of the borehole 26. Downbound ball logging tool 100 may be used in areas of interest as well as where there is a core loss. Loading data from the downbound ball logging tool 100 is significantly less burdensome than if you need to load and analyze the core sampler. By reducing the time it takes to receive the lithological data of the borehole, reliability in declaring the end of the drilling operation, that is, the "end of the hole" is increased, thereby improving the efficiency and reducing the work rate. The downward ballistic logging tool 100 may be used in conjunction with a core sample, or may be used entirely in place of the core sample provided sufficient information is provided.

By using an automatic actuation switch that automatically activates and deactivates the downward ballistic logging tool when it is removed (respectively) from the tool rack, the power consumption of the downward ballistic logging tool is advantageously reduced. Since the downward ballistic logging tool is typically removed from the tool rack only for use, the autostart switch will activate only the downward ballistic logging tool that is ready for use or is about to be used. This improves the life of the battery in the downward ballistic logging tool and also reduces overall power consumption.

The magnetic switching circuit 500 allows the magnetic sensitive reed switch 510 to be used without unduly limiting the current that can be supplied from the battery pack 502. Also, the circuit 500 avoids burn-out of the reed switch 510 during start-up.

Certain combinations of components of the downward ballistic logging tool have been described, including certain combinations of sensors and engagement. These particular combinations are preferred embodiments of the present invention, but it will be appreciated that other combinations of sensors and / or coupling portions may also be used.

Although referred to herein as a submersible drilling rig, it need not necessarily be a stationary drilling rig but may also be a movable drill rig, e.g. in the form of a remotely operated vehicle (ROV).

Here, references to seabed, underwater, etc. are merely for convenience and can be applied equally to other waters, such as lakes with lake bottoms.

In this specification, adjectives such as first, second, left and right, top, bottom, etc. are used only to distinguish one element or action from another, or action, It is not. When a context allows, reference to an integer, element, or step (or the like) should not be construed as being limited to only one such integer, element, or step, but rather may be one or more such integer, element or step.

The foregoing description of various embodiments of the invention has been presented for the purpose of illustration to those skilled in the art. The description is not exclusive or limiting the invention to one disclosed embodiment. As mentioned above, many alternatives and modifications to the present invention will be apparent to those skilled in the art from the above teachings. Accordingly, while some alternative embodiments have been described above, other embodiments will be apparent or may be developed relatively easily by those skilled in the art. The present invention includes all alternatives, modifications, and variations of the present invention discussed herein, as well as other embodiments falling within the spirit and scope of the invention as described herein.

As used herein, the terms "comprises," " comprising, "or like terms are intended to cover a non-exclusive inclusion and thus a method, system or apparatus that comprises the described elements, Other factors may also be included.

Claims (25)

A downhole logging tool used for subsea boreholes in underwater drilling operations,
An underwater chassis including an electronic component including a sensor and a power system; And
And an automatic operation switch that selectively provides power to the electronic component from the power system,
Wherein the sensor includes at least a conductive sensor and a magnetic sensitive sensor, and when the downward ballistic logging tool is located at a designated portion of a submarine drilling rig of a subsea drilling operation, the automatic operation switch is actuated to remove power from the electronic component And further provides power to the electronic component if the downward ballistic logging tool is not located at a designated portion of the submarine drilling rig. The method according to claim 1,
Wherein the autonomous switch comprises a magnetic switch operative when in proximity to a magnetic field source. 3. The method of claim 2,
Wherein said top field source is located at a designated portion of said undersea drilling rig. The method according to claim 2 or 3,
Said magnetic field source being located adjacent to a downward ballistic tool storage rack of a drilling rig. 5. The method according to any one of claims 2 to 4,
Wherein the magnetic switch is normally open and closed by a magnetic field of the magnetic field generator. 6. The method according to any one of claims 2 to 5,
Wherein the magnetic switch is a reed sensor that is part of an autonomous switch circuit comprising at least one transistor. The method according to claim 6,
Wherein the transistor is electrically coupled to a power source and the lead sensor switches the transistor to selectively provide power to the electronic component. 8. The method according to any one of claims 1 to 7,
Wherein the electronic component includes a data delivery system in communication with the sensor. 9. The method according to any one of claims 1 to 8,
Wherein the sensor includes a radial measurement sensor that performs measurements on a wall of the borehole. 10. The method according to any one of claims 1 to 9,
The downward ballistic logging tool further comprises a temperature sensor, a resistance sensor, and / or a natural gamma sensor. 11. The method of claim 10,
Wherein the resistance sensor is an inductive conductive sensor. 12. The method of claim 11,
Wherein the inductive conductive sensor is a dual coil inductive conductive sensor or a coil-focused inductive conductive sensor. 13. The method according to any one of claims 1 to 12,
Wherein the underwater chassis includes a coupling portion that is releasably secured to a corresponding coupling portion of the submarine drilling rig. 14. The method of claim 13,
And wherein the engagement includes a latch head coupling the downwardly-blanking tool to the wireline system. 14. The method of claim 13,
Wherein the coupling includes an adapter coupling the downwardly-blanking tool to the drill string. 16. The method according to any one of claims 1 to 15,
Wherein the power system includes a battery. 17. The method of claim 16,
Wherein the battery is rechargeable and the power system further comprises a battery charging system. 18. The method of claim 17,
Wherein the battery charging system is for inductively charging a battery from a subsea drilling rig. 18. A submarine drilling rig, comprising a downward ballistic logging tool according to any one of the preceding claims. A system using downbound ball logging tools in subsea drilling operations,
Includes a downward ballistic logging tool including a power system, a sensor, and an autonomous operation switch across the borehole,
Wherein the sensor includes at least a conductive sensor and a magnetic sensitive sensor, the automatic operation switch selectively providing power from the power system to a sensor of a downbound ballistic tool,
The automatic operation switch activates the downward ballistic logging tool when the downward ballistic logging tool leaves a designated portion of the undersea drilling rig and also deactivates the downward ballistic logging tool when the downward ballistic logging tool enters a designated portion of the undersea drilling rig Wherein the system uses downbound logging tools in subsea drilling operations. CLAIMS 1. A method of using a downbound ball logging tool in a subsea drilling operation,
Selecting a downward ballistic logging tool to traverse the seabed borehole;
Moving the selected downward ballistic logging tool from a designated portion of the submarine drilling rig; And
When the downward ballistic logging tool leaves the designated portion of the drilling rig and activates the downward ballistic logging tool and the downward ballistic logging tool enters the designated portion of the undersea drilling rig, And automatically actuating the automatic operation switch of the downwardly grounding tool. 22. The method of claim 21,
Connecting the downward ball logging tool to the wire line;
Lowering the downward ball logging tool through the drill string into the submarine borehole;
Placing the downward ballistic logging tool in the receiving portion of the lowermost drill string;
Separating and retracting the wire line; And
Further comprising performing a measurement with a downward tool when the drill string is removed from the borehole. 23. The method of claim 21 or 22,
Wherein the downward ballistic tool has a sensor including at least a conductive sensor and a magnetic sensitive sensor. 24. The method according to any one of claims 21 to 23,
Wherein the downbound logging tool performs a radial directional measurement on a wall of the borehole. 25. The method according to any one of claims 21 to 24,
Wherein the downward ballistic logging tool is a downward ballistic logging tool according to any one of the preceding claims.

Images