BR112019019176A2 - sensor configuration - Google Patents

Abstract

a sensor configuration including a centralizer having a rib, a defined cavity within the rib and a sensor positioned within the cavity. a hole system including a hole, a tubular column disposed within the hole, a centralizer having a rib and the rib defining a cavity, disposed in the tubular column, a sensor within the cavity. a method for acquiring data in a hole, including descending a sensor configuration as in any previous modality in a tubular column in a hole, cementing the tubular column in the hole and detecting with a sensor configuration a parameter in the hole.

Description

SENSOR CONFIGURATION

FUNDAMENTALS [0001] In the resource exploration and recovery industry, information about conditions in the rock bottom environment is often useful. A particular example of information is to know the condition of the integrity of the cement, they are means to determine such information available in the technique, which include descending a steel cable into a hole after the completion of a cementation job and detecting the parameters related to cement integrity. The results of the method are generally good, but this method requires an additional descent with a steel cable. The probe time is increasingly expensive and, at the time this disclosure was written, the value is over one million dollars a day. Although it is possible to relinquish information, it is preferable to have more, rather than less, information about rock bottom conditions in order to avoid inactivity, inefficiencies, etc. Consequently, the technique would approve alternative configurations that provide information about the bottom of the well environment, but also reduce the time of the probe.

SUMMARY [0002] A sensor configuration including a centralizer having a rib, a defined cavity within the rib and a sensor positioned within the cavity.

[0003] A hole system including a hole, a tubular column disposed within the hole, a centralizer having a rib and the rib defining a cavity, disposed in the tubular column, a sensor within the cavity.

[0004] A method for acquiring data in a hole, including descending a sensor configuration as in any previous modality in a tubular column in a hole, cementing the tubular column in the hole and detecting with a sensor configuration a parameter in the hole .

BRIEF DESCRIPTION OF THE DRAWINGS [0005] The following descriptions should not be considered as limiting under any circumstances. In reference to the accompanying drawings, similar elements are enumerated in a similar way:

[0006] Figure 1 is a schematic illustration of a hole with a tubular member inside and a solid body centralizer as described here;

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2/7 [0007] Figure 2 is a cross-sectional view of the centralizer shown in figure 1; and [0008] Figure 3 is an illustration similar to Figure 1, but includes another column in the hole.

DETAILED DESCRIPTION [0009] A detailed description of one or more modalities of the disclosed apparatus and method is presented in this document as an example, and not as a limitation, with reference to the Figures.

[0010] With reference to Figure 1, a sensor configuration 10 is illustrated in situ. The figure includes the hole 12 into which a column of tubular 14 is also arranged, the configuration of the sensor being arranged around the column. The sensor configuration 10 comprises a centralizer 16 with a sensor 18 (although the term sensor can mean only one sensor per se, it is here widely intended to also include electronics and / or an associated power source) (one or more sensors in one or more centering ribs), as discussed in more detail below. Centralizers 16 are commonly used to maintain a tubular column at or near the central axis of a hole 12 in which the tubular column 14 is arranged. Types of centralizers known in the art include solid body centralizers (having an inner diameter surface that fits into a tubular and a body of material that includes ribs, the material being essentially a solid mass or expanded mass or machined into a tubular as a stabilizer in a lower hole assembly). Centralizers can be constructed from most materials with sufficient compressive strength to function as a centralizer in a rock bottom environment. Determining the suitability of a particular material for the task at hand is well within the skill level of one skilled in the art. Metallic material and polymeric material are two examples of materials that can be used.

[0011] Referring to Figure 2, a cross-sectional view of a sensor configuration 10, as disclosed herein, is illustrated. The sensor configuration 10, as noted earlier, comprises a centralizer 16 and a sensor 18 arranged therein. The centralizer 16 is of a solid body type, seen from its exterior, with ribs 20 (helical or axially straight or of any other configuration) that extend radially outward from a body 22. One or more of the ribs 20 define a

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3Π cavity 24 in it of sufficient size to accommodate sensor 18 (and / or electronic and / or power source). It should be understood that the particular dimensions of the cavity 24 can be different in several iterations of the sensor configuration, depending on the particular size and type of sensor selected for use. A particular sensor contemplated for use in this configuration is a piezoelectric transducer used in a commercial tool known as a segmented connection tool (SBT) available from Baker Hughes Incorporated Houston Texas from SBT is positioned inside cavity 24. Sensor 18 can be configured to operate with battery energy (arranged in the cavity with the sensor), inductive energy from another tool descended into the well afterwards, energy generated at the bottom of the well, etc. electronics needed to control the sensor and the power supply (both collectively under the shadows of numeral 18) can also be located in cavity 24.

[0012] The sensor configuration 10 must be arranged in the tubular 14 in the same way that the solid body centralizers of the prior art are used specifically, the centralizer 16 is arranged in the tubular 14 and fixed in place. In an alternative embodiment, the centralizer 16 can be located between two segments of tubular 14 similar to a stabilizer in a drill string. Fixation can be by welding, threading or any other fixation method known in the art for fixing centralizers or stabilizers. It is important to note that the centralizer has no impediment to the flow area of the tubular inner diameter 14. The sensor 18 containing ribs 20 is located in the annular space outside the tubular 14. The sensors for past cement integrity checks went down in ID of the pipe column 14, thus, necessarily, an impediment to the flow, but also needing the separate descent of the steel cable that the disclosure here avoids. The sensors 18, being present with the cavity 24 and in some modalities being sealed inside the cavity 24 also have no impact on the flow area inside the tubular 14. Of the possible types of sensors that can be used in the cavity (s) 24, some include cement integrity sensors, pressure sensors, temperature sensors, etc. or combinations including at least one of the above. In addition, since more than one rib will generally be part of a centralizer, it is contemplated to have one or more different sensors on different ribs. Alternatively indicated, in a modality in which there are four ribs and in which each of these four ribs has a cavity,

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4/7 there can be four sensors of the same type, three identical and one different, a different sensor on each rib, some ribs without sensors, etc. More than one type of sensor is also contemplated in a single cavity in iterations.

[0013] In conjunction with modalities that include, one. cement integrity sensor, in addition to the SBT sensor mentioned earlier, other sensors such as Electromagnetic Acoustic Transducers (EMATs), wedge transducers, pulse-echo transducers, pitch-catch configuration or combinations including at least one of the above are included. It should be understood that the location of the cement integrity sensor in the ribs 20 is advantageous in itself for sensors of the SBT type. Specifically, the sensors positioned outside the tubular 14 bring them closer to the cement that the sensor must examine and avoid the need for a sensory signal to pass through the tubular column itself 14, as would be the case in prior art systems.

[0014] Regardless of the type of sensor used, the sensor configuration is a permanent part of the tubular column 14 and therefore allows sensory readings over time with the related storage of this sensory information within an internal memory in the sensor 18 The stored information can be sent to the surface through a communication conduit placed in place with the tubular column 14 or it can be downloaded to a posterior descent tool 26, such as a drilling rig, a completion hill, etc. ., which includes an interrogator 28 (see figure 3). And while one of the benefits of configuring the sensor is to avoid the need for a dedicated descent to obtain sensory information, such as a descent with a steel cable, it is possible to descend a dedicated interrogation tool to receive the data stored in the sensor 18.

[0015] The modalities contemplated here can be manufactured by traditional manufacturing methods or by additive manufacturing methods.

[0016] A method for acquiring data from a hole is also contemplated including having a centralizer that defines a cavity in. a rib and a sensor in the cavity in a pipe column; collect data with the sensor. Data can be collected over time, since the sensor is permanently mounted on the tubular column in the hole. The sensor can communicate the data or store the data for future delivery to one. interrogator. The interrogator can descend into a tool that has a primary function other than an interrogator, such as a drill set,

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5/7 completion, wire rope, wire, etc. The data can be of any type, including data for previously established parameters.

[0017] The following are some modalities of the previous disclosure:

[0018] Mode 1: A sensor configuration including a centralizer having a rib, a defined cavity within the rib and a sensor positioned inside the cavity.

[0019] Mode 2: The sensor configuration as in any previous mode in which the centralizer is a solid body centralizer.

[0020] Mode 3: The configuration of the sensor as in any previous mode in which the sensor is completely contained within the cavity.

[0021] Mode 4: The sensor configuration, as in any previous mode, in which the sensor is sealed inside the cavity.

[0022] Mode 5: The sensor configuration, as in any previous modality, in which the sensor is a cement integrity sensor.

[0023] Mode 6: The sensor configuration, as in any previous modality, in which the sensor is a temperature sensor.

[0024] Mode 7: The sensor configuration, as in any previous mode, in which the sensor is a pressure sensor.

[0025] Mode 8: The configuration of the sensor, as in any previous modality, in which the rib is more than a rib, at least more than one of more than one sensor containing rib.

[0026] Mode 9: The sensor configuration, as in any previous mode, in which the sensors are selected from the same type of sensor or different sensors for more than one of more than one rib.

[0027] Mode 10: The configuration of the sensor, as in any previous mode, in which the centralizer comprises a metallic material.

[0028] Mode 11: The configuration of the sensor, as in any previous mode, in which the centralizer comprises a polymeric material.

[0029] Mode 12: A hole system including a hole, a tubular column disposed inside the hole, a centralizer having a rib and the rib defining a cavity, disposed in the tubular column, a sensor inside the cavity.

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6/7 [0030] Mode 13: A method for acquiring data in a hole, including descending a sensor configuration as in any previous modality in a tubular column in a hole, cementing the tubular column in the hole and detecting with the configuration of the sensor a parameter in the hole.

[0031] Mode 14: The method, as in any previous modality, in which the detection is over time.

[0032] Mode 15: The method, as in any previous mode, also includes descending another tool whose primary function is not the interrogation of the sensor with an interrogator on it.

[0033] Mode 16: The method, as in any previous modality, in which the tool is a drilling set.

[0034] Mode 17: The method, as in any previous mode, in which the tool is a completion column.

[0035] The use of the terms "one (a)" and "o / a" and similar referents in the context of describing the invention (especially in the context of the following claims) should be interpreted to encompass both the singular and the plural , unless otherwise specified in this document or in the event of a clear contradiction in context. In addition, it should also be noted that the terms "first", "second" and the like in this document do not denote any order, quantity or importance, but are used instead to distinguish one element from another. The “about” modifier used in conjunction with a quantity is inclusive of the declared value and has the meaning dictated by the context, (for example, includes the degree of error associated with the measurement of the particular quantity).

[0036] The teachings of the present disclosure can be used in a variety of well operations. Such operations may involve the use of one or more treatment agents to treat a formation, fluids residing in a formation, a well bore and / or equipment in the well bore, such as the production pipe. The treatment agents can be in the form of liquids, gases, solids, semi-solids and mixtures thereof. Illustrative treatment agents include, but are not limited to, fracturing fluids, acids, steam, water, brine, anti-corrosion agents, cement, permeability modifiers, drilling muds, emulsifiers, demulsifiers, indicators, flow improvers, etc. . but are not limited to, hydraulic fracturing, stimulation,

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ΊΠ indicator injection, cleaning, acidification, steam injection, water flooding, cementation, etc.

[0037] Although the invention has been described with reference to examples of modalities, it will be understood by those skilled in the art that various changes can be made and equivalents can be replaced by elements thereof without departing from the scope of the invention. In addition, many modifications can be made to adapt a particular situation or material to the teachings of the invention without departing from its essential scope. Therefore, it is intended that the invention is not limited to the specific modality disclosed as the best mode contemplated for the realization of this invention, but that the invention includes all modalities covered by the scope of the claims. In addition, in the figures and in the description, examples of modalities of the invention have been disclosed and, although specific terms may be used, they are, unless otherwise indicated, used in a generic and descriptive sense and not for the purpose of limitation , the scope of the invention, therefore, is not so limited.

Claims (17)

1. Sensor configuration (10), characterized by the fact that it comprises: a centralizer (16) having a rib (20); a cavity (24) defined within the rib (20); and a sensor (18) positioned inside the cavity (24). 2. Sensor configuration (10), according to claim 1, characterized by the fact that the centralizer (16) is a solid body centralizer. 3. Sensor configuration (10), according to claim 1, characterized by the fact that the sensor (18) is completely contained within the cavity (24). 4. Sensor configuration (10), according to claim 1, characterized by the fact that the sensor (18) is sealed inside the cavity (24). 5. Sensor configuration (10) according to claim 1, characterized by the fact that the sensor (18) is a cement integrity sensor. 6. Sensor configuration (10), according to claim 1, characterized by the fact that the sensor (18) is a temperature sensor. 7. Sensor configuration (10) according to claim 1, characterized by the fact that the sensor (18) is a pressure sensor. 8. Sensor configuration (10) according to claim 1, characterized by the fact that the rib (20) is more than a rib (20), at least more than one of more than one rib (20) containing sensors (18). 9. Sensor configuration (10) according to claim 8, characterized by the fact that the sensors (18) are selected from the same type of sensor (18) or different sensors (18) for more than one of more than one rib (20). 10. Sensor configuration (10) according to claim 2. characterized by the fact that the centralizer (16) comprises a metallic material. 11. Sensor configuration (10) according to claim 2, characterized by the fact that the centralizer (16) comprises a polymeric material. 12. Hole system, characterized by the fact that it comprises: a hole (12); a tubular column (14) disposed inside the hole (12); a centralizer (16) having a rib (20) and the rib (20) defining a cavity (24), arranged in the tubular column (14); Petition 870190092156, of 16/09/2019, p. 18/48 2/2 a sensor (18) inside the cavity (24). 13. Method for acquiring data in a hole (12), characterized by the fact that it comprises: down a sensor configuration (10) as claimed in. 1 in a tubular column (14) inside a hole (12); cement the tubular column (14) into the hole (12); and detecting, with the sensor configuration (10), one. parameter in the hole (12). 14. Method according to claim 12, characterized by the fact that the detection is over time. 15. Method according to claim 11, characterized by the fact that it also includes another tool (26) whose main function is not to interrogate the sensor with an interrogator (28) on it. 16. Method according to claim 12, characterized by the fact that the tool (26) is a drilling set. 17. Method according to claim 12, characterized by the fact that the tool (26) is a completion column.