Patent Application
20220268151
This disclosure generally relates to apparatus, systems, and methods to convey a tool string into a wellbore. Conveyance of tool strings often requires several pieces of equipment including a winch, cable, pully system, and other wireline surface equipment to convey a wireline tool string into a wellbore; however, deployment and setup of the wireline surface equipment is often time consuming and inefficient.
Therefore, a need exists for apparatus, systems, and methods to convey a tool string into a wellbore that reduces the amount of surface equipment required to convey the tool string into the wellbore.
A method of conveying a logging tool into a wellbore. The method can include placing an apparatus into a drill pipe in a wellbore, wherein the apparatus is configured to be conveyed by mud pumping into the drill pipe. The method can also include adjusting a mud pulser on the apparatus to selectively open or close a mud outlet in the apparatus. The method can also include landing the apparatus in a landing portion.
A system for conveying a tool string into a wellbore can include an apparatus as disclosed herein. The system can also include a logging tool string connected with a lower portion of the apparatus. The system can also include a drill pipe having a landing portion at a lower end thereof.
In an embodiment, the apparatus can include a seal module located on an upper portion of the apparatus. The apparatus can also have a lower portion configured to connected to a tool string, and the apparatus can be configured to communicate with the surface.
In another embodiment, the apparatus can include a seal module located at an upper portion thereof and a mud line formed through the upper portion of the apparatus. The apparatus can also include a mud outlet in fluid communication with the mud line. The apparatus can also include a mud pulser adjacent the mud outlet, wherein the mud pulser is configured to be actuated to open, partially close, and close the mud outlet. The apparatus can also include a mud pulser harness connected with the apparatus between the mud pulser and a swivel, wherein the mud pulser harness is connected with the mud pulser and the swivel. The apparatus can also include a control module adjacent the swivel, wherein the swivel provides communication between the control module and the mud pulser harness.
Various aspects of this disclosure may be better understood upon reading the following detailed description and upon reference to the drawings in which:
One or more specific embodiments of the present disclosure will be described below. These described embodiments are examples of the presently disclosed techniques. Additionally, in an effort to provide a concise description of these embodiments, features of an actual implementation may not be described in the specification. It should be appreciated that in the development of any such actual implementation, as in any engineering or design project, numerous implementation-specific decisions may be made to achieve the developers' specific goals, such as compliance with system-related and business-related constraints, which may vary from one implementation to another. Moreover, it should be appreciated that such a development effort might be complex and time consuming, but would be a routine undertaking of design, fabrication, and manufacture for those of ordinary skill having the benefit of this disclosure.
In one or more embodiments a method of conveying a tool string into a wellbore can include placing an apparatus with a tool string attached to an end thereof into a drill pipe in wellbore. The apparatus can be used to convey an attached tool string into the wellbore without a tether to surface equipment, thereby allowing a tool string to be conveyed without additional surface equipment and using standard equipment of a rig that is used to run pipe into the wellbore, drill the wellbore, or combinations thereof. To accomplish this the apparatus is configured to be pumped down, using a standard mud pump used in typical drilling operations, in a controlled manner.
The method can also include providing data to the surface. The data can be provide to the surface using mud pulse telemetry, electromagnetic telemetry, other types of telemetry or combinations thereof.
In one or more embodiments of the method the telemetry can be mud pulse telemetry and the method can further include adjusting a mud pulser on the apparatus to selectively open, partially close, or close a mud outlet in the apparatus. The selective operation of the mud pulser allows for data to be conveyed to the surface for viewing or storage. The data acquired and sent to the surface during conveyance of the apparatus, using the mud pulse communication, can include tool health data, conveyance data, wellbore condition data, formation data, evaluation data, or combinations thereof. The tool health data can be the status of a power supply in communication with the tool string, status of components of the tool string, or the like. The conveyance data can used depth, acceleration data, conveyance speed data, or the like. The wellbore condition data can include pressure, temperature, or the like. In one or more embodiments, the conveyance data can include data from one or more accelerometers on the tool string or apparatus, for example, one or more three axis accelerometers can be placed on various locations of the apparatus and tool string, the data can be uplinked to the surface using the selective actuation of the mud pulser following a communication scheme, and rig sensors, for example a sensor configured to measure standpipe pressure, can take the mud pulse data and send it to the rig system, and an external system can be linked to the rig system. The external system can include one or more processors configured by computer instructions in communication with the processors to convert the accelerator data into velocity (i.e., integrate the accelerator data over time), and position (i.e., integrate the velocity data over time), and display the velocity and position of the apparatus on a display. The processor can also be configured to form a trace of the apparatus path of travel and provide into a map or model of the wellbore that was created during drilling to help fine tune the map or model, issue an alert if the axial velocity is over a predetermined value, issue an alert if lateral velocity or acceleration is detected or above a predetermined value, issue a command to the rig system to adjust the mud pump rate if the velocity is over a predetermined value or below a predetermined value, issue an alert if upon detection of the displacement of the tool string is such that it is approaching the landing portion of the drill pipe, determine using accelerator data and displacement value to detect that the apparatus is landed in the in the landing portion of the drill pipe, and confirm, adjust, or combinations thereof the depth data of the landing portion using the displacement data when the apparatus is confirmed landed in the landing, other determinations by processing the sensor data on the apparatus or tool string to determine a desired value. The apparatus can also include sensors to detect the shock or force imparted to the apparatus when the apparatus lands in the landing portion. In one more embodiments, the shock or force imparted to the apparatus during landing can with a model of the tool in communication with the one or more processors to predict the health of the tools, simulate the actions at landing to determine if there is potential damage to any of the components, or predict how many more landings the apparatus can take before needing maintenance, or the like.
The mud pulser can be selectively operated, as described in more detail below, to send data to the surface. The data can include tool string health data, evaluation data collected using one or more formations evaluation sensors or fluid testing sensors on the tool string, operation data, or combinations thereof. In one or more embodiments, the operation data can be a signal the memory is recording evaluation data, motor torque, pump pressure, actuation of an anchor or evaluation pad, the movement of a mechanical intervention or coring bit; test pressure of a formation evaluation tool, weight on bit of a coring bit, or other operation data. Tool string health data can be signal indicating all major components passed an operation check, a signal that something is not connected, or other tool string health data.
In one or more embodiments, the telemetry can be electromagnetic telemetry. The electromagnetic telemetry can use now known electromagnetic telemetry systems or future known electromagnetic telemetry. For example, the electromagnetic telemetry can use the TelePacer™ modular MWD platform with Express™ electromagnetic telemetry available from Schlumberger™.
In one or more embodiments, the method can include acquiring evaluation data as the apparatus and tool string are being conveyed to detect increase in density, thereby indicating that the apparatus is passing a drill pipe joint, and deriving the speed and location of the tool string during conveyance. The evaluation data can be acquired using a logging tool string, casing collar locator, or combinations thereof. For example, radioactive measurement such as gamma measurements, neutron-gamma measurements, X-ray measurements, the like, or combinations thereof. The method can also include sending the evaluation data to the surface and modulating mud flow rate in the bore to optimize the conveyance of the tool string.
In one or more embodiments, the method can include acquiring evaluation data during conveyance to detect changes in density, process the acquired data downhole to determine apparatus speed, location, or combinations thereof, transmit the determined speed, location, or combinations thereof to the surface, and modulate the mud pump rate to the borehole based on the determine location, speed, or combinations thereof. The method of claim 11, further comprising processing the evaluation data downhole to determine the speed, location, or combinations thereof and sending the determined speed, location, or combinations thereof to the surface. In one or more embodiments, the determined speed, location, or combinations thereof is used to automatically modulate the mud pump flow rate. For example, the surface equipment can have a processor and data acquisition system configured to receive the determined speed, location, or combinations thereof and the processor can be in communication with computer instructions that take the determined speed, location, or combinations thereof and automatically determines the optimized pump rate and controls the mud pumps to modulate the pump rate to the optimized pump rate. The optimized pump rate can be determined by predetermined values based on the location, speed, or the like. For example, the computer instructions can include or be in communication with a planner that says at x depth the speed should be n, if the speed of the apparatus at x depth is greater than n the computer instructions would instruct the processor to calculate the pump rate that will reduce the speed to match n and control the mud pumps to adjust the pump rate accordingly, and if the speed of the apparatus at x depth is less than n the computer instructions would instruct the processor to calculate the pump rate that will increase the speed to match n and control the mud pumps to adjust the pump rate accordingly.
In one or more embodiments, the method can include providing automated pump rate control based on downhole tool speed. The tool speed can be determined from data acquired from casing collar locaters, wheels on the apparatus or tool string, accelerometers on the apparatus or tool string, and pressure drop along tool string
In one or more embodiments, the pressure drop can be determined using pressure gauges located at upper portion and lower portion of the apparatus and tools string. The pressure difference between both value is equal to the pressure drop in the drill pipe between both points of the tool string. This can give us an indication of the pumping efficiency.
The control module described in more detail below can include one or more additional modules which can be connected and in communication with one another. In one or more embodiments, the control module or a module in communication with the control module can be configured to provide conveyance monitoring and decision processing. The conveyance monitoring and decision processing will receive input from: a casing collar locator, one or more accelerometers, one or more wheels contacting the drill pipe ID, a top pressure gauge, a bottom pressure gauge, or combinations thereof. A processor in the module will be configured by computer instruction in communication with the processor to process the data to derives downhole speed while deploying during pump down, and the pressure drop along the string. The derived speed and pressure drop can be used to determine a recommended pump rate. The recommended pump rate can be communicated to the surface using telemetry. For example, the recommend pump rate can be communicated to surface using mud pulse temerity. Any type of mud pulse communication protocols can be used to communicate the recommend pump rate to the surface. For example, a pressure pulse every minute when the tool string speed is close to the desired pump down speed; increased pressure pulse frequency when the tool string speed is above the desired pump down speed; a decreased pressure pulse frequency when the tool string speed is below the desired pump down speed; the like; or combinations thereof. The pressure pulses are interpreted at surface and the pump rate is adjusted by modulating the pump rate or diverting a portion of the flow.
Furthermore, the top pressure sensor and bottom pressure sensor measurements can be matched against each other with the knowledge of deviation, mud density, and distance between sensors, or when deviation is 90 degrees. The pressure sensors can be used to derive pressure drop along the string (indication of force exerted by the flow onto the string); receive downlink mud pump commands; shut down the tools after the interval is completed before the tool strings reaches the surface; or combinations thereof.
The retrieval neck 110 is located at an end of the apparatus and a tool string 190 is connected at the other end of the apparatus 100. The retrieval neck is configured to allow the apparatus and tool string to be retrieved via a retrieval operation if needed. The retrieval neck can be any now known or future known retrieval neck. The tool string 190 can be a logging tool string, a collar locator, intervention tool string, other known or future know tools strings, or combinations thereof. Examples of logging tool strings include nuclear logging tool strings, a resistivity logging tool strings, nuclear magnetic resonance logging tool strings, dielectric logging tool strings, micro resistivity logging tool strings, xray logging tool strings, other now known or future known logging tool strings, or combinations thereof.
The seal module is located adjacent the retrieval neck. The one or more seal modules 120 can be one or more wiper plugs, one or more swab cups, or one or more other device to add drag and seal on the drill pipe bore. The seal module 120 can be made from any material, such, as a flexible rubber, flexible polymer, or other flexible composite. The seal module 120 provides a seal during deployment and provides substantially positive displacement, allowing pump down conveyance with low pump rates, medium pump rates, or high pump rates. The one or more mud lines, shown as one mud line 130 provides a flow path through a top portion of the apparatus 100 to one or more mud outlets, depicted as one mud outlet 140.
One or more mud pulsers, depicted as a single mud pulser 150, can be located adjacent the mud outlet 140. The mud pulser 150 can be connected with one or more mud pulser harnesses, depicted as one mud pulser harness 152. The mud pulser harness 152 can be connected to the swivel 170. The swivel 170 can be a multi-contact swivel that provides communication between the one or more control modules, shown as control module 180. The multi-contact swivel can also accommodate rotation of the drill pipe while tripping out without cause loss of communication between the pulser harness and control module 180. The swivel 170 can also allow the tool string to self-position in the borehole wall, independent from the face of the drill pipe. The swivel 170 can have one or more rotatable electrical connections, for example one for communication signals and one for power. Accordingly, the mud pulser harness can allow communication between the mud pulser 150 and the control module 180, allowing power, signals, or combinations thereof to be sent between the mud pulser 150 and control module 180. One or more decelerators can be located on the apparatus, one decelerator 160 is depicted disposed between the mud outlet 140 and the control module 180.
The mud pulser 150 can be any now known or future known mud pulser. In one or more embodiments, the mud pulser 150 can be a linear valve type. In one or more embodiments it can include a plunger. The mud pulser 150 can be actuated by an actuation system, embodiments of the actuation system are described in more detail below. Another example, of the mud pulser is a rotary siren mud pulser, for example the mud pulser can include a rotor working in combination with a stator to selectively at least partially restrict, fully restrict, or open the mud inlet. The mud pulser can include other flow control device such as solenoid valves or the like.
The decelerator 160 can be a mechanical device configured to be self-actuating, an actuated from a control system, or combinations thereof. For example, the decelerator can have an electric actuator that is activated by the control module 180 when data from an accelerometer is above a predetermined value or range or the like, e.g., proximity to the landing portion and velocity, or the like.
The control module 180 can include one or more communication modules, one or more power modules, one or more microprocessor, one or more communication bus, or combinations thereof. The control module collects data from the other tools of the tool string, summarizes the data, and generate a status word under the form of a predefined pulse communication pattern.
The communication scheme can be a pulse width modulation between the high and low pressure drop states described above for each position. For example, a 15 second period means the tool string is functioning properly, while a 20 second period means the tool string has an issue.
When introducing elements of various embodiments of the present disclosure, the articles “a,” “an,” and “the” are intended to mean that there are one or more of the elements. The terms “comprising,” “including,” and “having” are intended to be inclusive and mean that there may be additional elements other than the listed elements. Additionally, it should be understood that references to “one embodiment” or “an embodiment” of the present disclosure are not intended to be interpreted as excluding the existence of additional embodiments that also incorporate the recited features.
The decelerator 1000 can have a fluid of known properties (not shown), such as hydraulic fluid, oil, grease or the like, trapped in an annular cavity 1040 whose volume varies when an outer landing sleeve 1030 moves. For example, the outer landing sleeve 1030 can slide. The outer landing sleeve 1030 can be disposed about to the apparatus. The apparatus can have a stop 1060. The annular cavity 1040 can be sealed by one or more seals 1050.
Initially, during conveyance, the annular cavity 1040 is filled with the fluid of known properties. At landing, the internal overpressure generated by the impact of the no-go onto the sliding sleeve opens a relieve valve 1010 that allows the landing sleeve 1030 to slide and the contained hydraulic fluid to flow out.
During deceleration, the fluid of known properties is pushed out of the annular cavity 1040 thru extra grooves on the inner wall of the landing sleeve 1030. The pressure relieve valve 1010 is used to equalize the pressure between inside and outside of the annular cavity 1040 when the specific volume of the mud increases due to pressure and temperature effects. The energy absorbed during the process can be tuned by: varying the properties of fluid of known properties, the volume of fluid of known properties, or combinations thereof; varying the valve opening threshold; varying the opening size of the cuts 1020 on the landing sleeve 1030, or combinations thereof.
Although example assemblies, methods, systems have been described herein, the scope of coverage of this patent is not limited thereto. On the contrary, this patent covers every method, apparatus, and article of manufacture fairly falling within the scope of the appended claims either literally or under the doctrine of equivalents.
The present document is based on and claims priority to U.S. Provisional Application Ser. No. 62/878,166, filed Jul. 24, 2019, which is incorporated herein by reference in its entirety.
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/US2020/043246 | 7/23/2020 | WO |
| Number | Date | Country | |
|---|---|---|---|
| 62878166 | Jul 2019 | US |
