CN206158732U - Nearly drill bit drilling tool gesture is along with boring measuring device - Google Patents

Abstract

The utility model relates to a device for measuring the attitude of a drilling tool near a drill bit while drilling, which comprises a measuring sensor and a measuring circuit. The measuring signal of the measuring sensor is transmitted to the measuring circuit, and the measuring circuit processes and calculates the signal to obtain attitude data. The measurement sensor includes a three-axis accelerometer, a three-axis gyroscope, a three-axis magnetic sensor and a temperature sensor, and uses the temperature sensor measurement data to correct the measurement data of the three-axis accelerometer, the three-axis gyroscope and the three-axis magnetic sensor respectively, and utilizes The measured data of the corrected three-axis accelerometer and the three-axis magnetic sensor are used to calculate the attitude angle 1, and a pair of quaternions are used to initialize the attitude angle, and the time update of the initialized quaternion is performed according to the measurement data of the three-axis gyroscope. Then, the updated quaternion is used to calculate the attitude angle, and the cumulative error of the three-axis gyroscope is eliminated by periodically initializing the quaternion, thereby improving the accuracy of the near-bit drill tool attitude measurement while drilling.

Description

A near-bit drilling tool attitude measurement device while drilling

technical field

The utility model mainly belongs to the field of measurement-while-drilling of petroleum drilling, in particular to a device for measuring the attitude of drilling tools near a drill bit while drilling.

Background technique

Directional Drilling (Directional Drilling) is a drilling technology that allows the wellbore to drill to the underground target layer along a pre-designed trajectory. The use of directional drilling technology can economically and effectively develop oil and gas resources with limited surface and downhole conditions, can greatly increase oil and gas production and reduce drilling costs, is conducive to environmental protection, and has significant economic and social benefits. During directional drilling, the orientation information of the drill bit is crucial for correct drilling. Accurate measurement of the attitude of the downhole drilling tool can not only ensure the efficient drilling of the target, but also avoid the risk of collision with the adjacent wellbore. Therefore, in addition to the traditional bottom hole assembly (including drill bits, screw drilling tools, centralizers, drill collars, etc.), directional drilling tools need to use position sensors to measure the attitude of the downhole drilling tool, including the azimuth (the angle of deviation from the north on the horizontal plane ), inclination (the deviation angle from the vertical direction, also known as well inclination angle) and tool face angle (equivalent to the roll angle in navigation).

With the deepening of oilfield exploration and development, the development of thin oil reservoirs, fault block oil reservoirs, marginal oil reservoirs, remaining oil reservoirs and other hard-to-produce reserves has been developed on a large scale, and the requirements for trajectory control accuracy are also increasing. In the exposed area of the wellbore, to increase the production of the oil well, it is required to drill through the reservoir with an accurate wellbore trajectory. In order to accurately obtain the trajectory parameters at the drill bit, the distance between the downhole trajectory parameter sensor and the drill bit (measuring point zero length) is very important. The attitude measurement tool of the existing Measurement While Drilling (MWD) system is usually located behind the deflection tool, and measures parameters such as well inclination, azimuth, and tool face at a position 8-20 meters away from the bottom hole bit. It is impossible to judge the actual situation of entering the reservoir from the position of the wellbore at the drill bit.

The existing measurement-while-drilling (MWD) system, from the perspective of the principle of attitude angle measurement, includes two main technical lines based on magnetic sensors and accelerometers, and based on gyroscopes and accelerometers.

(1) MWD system based on magnetic sensor and accelerometer

The angle measurement unit of this type of MWD system consists of three orthogonal accelerometers and three orthogonal magnetic sensors. The accelerometer is usually a quartz flexible accelerometer, and the magnetic sensor is usually a fluxgate magnetometer. Accelerometer measurements are used to calculate inclination and tool-face angles, while azimuth is obtained using inclination, tool-face angle, and geomagnetic field data. Since bearings are measured with reference to magnetic north, magnetometers require a non-magnetic environment. The main problem facing the current magnetometer-based MWD system is magnetic interference, which mainly includes the magnetic interference of the drill string itself and the external magnetic interference generated by the surrounding environment. The drill string magnetic interference mainly affects the magnetometer along the direction of the drilling tool rotation axis, while the external magnetic interference has an impact on the three magnetometers. The external magnetic interference mainly comes from the formation of ferromagnetic casing and pyrite in nearby production wells. , solar storms, drilling fluid components, magnetic hotspots, etc. The existence of magnetic interference seriously affects the accuracy of azimuth measurement. The conventional MWD system is usually installed in the middle of the nearly 9-meter-long non-magnetic drill collar to isolate the magnetic interference of the upper and lower drill pipes as much as possible, but the attitude measurement device near the drill bit needs to be installed close to the drill bit. more serious.

(2) MWD system based on gyroscope and accelerometer

This type of MWD system uses a gyroscope to measure the change of angular velocity along the sensitive axis of the sensor, and has been applied in the field of directional drilling. The advantage of gyro technology lies in applications where the earth's magnetic field is shielded or where magnetic interference is severe, because magnetic interference will not affect the performance of the gyro. Affected by factors such as instrument size, vulnerability to vibration and impact, and gyro measurement accuracy, gyro technology is currently mainly used in wired measurement systems, and there are still certain limitations in the application of drilling while drilling. The biggest problem of the MWD system based on the gyroscope and the speedometer is that the output signal of the angular velocity gyro has a large drift rate, and the integrated attitude angle diverges quickly, which will introduce a large steady-state error. However, there is a cumulative error, especially in the downhole high-temperature environment, and the volume and reliability are difficult to meet the harsh working conditions while drilling and the narrow space near the drill bit.

To sum up, no matter the MWD system based on magnetic sensor and accelerometer or the MWD system based on gyroscope and accelerometer, there are limitations in the application occasions, especially for near-bit drilling tool attitude measurement, it is difficult to meet the requirements of high temperature and strong bottom hole. Vibration shock, strong magnetic interference, limited installation space and other complex application environments.

Utility model content

In view of the above problems, the utility model proposes a downhole drilling tool attitude measurement device while drilling based on the combination of micro-inertia and geomagnetism, and uses the combined attitude measurement technology to overcome the inherent defects of the single attitude measurement method (micro-inertial device cumulative error problem and Geomagnetic field measurement interference), through multi-sensor information fusion, the attitude measurement accuracy of downhole drilling tools can be effectively improved.

The utility model is achieved through the following technical solutions:

A device for measuring the attitude of a near-drill drill tool while drilling is characterized in that it includes a measurement sensor and a measurement circuit, the measurement signal of the measurement sensor is transmitted to the measurement circuit, and the measurement circuit processes and calculates the signal to obtain attitude data. The measurement sensor includes a three-axis accelerometer, a three-axis gyroscope, a three-axis magnetic sensor and a temperature sensor, and the measurement circuit includes an analog-to-digital converter, a field programmable gate array (FPGA), a memory, a processor and a low-pass A filter, the filter is connected with the measurement sensor, the filter is connected with the analog-to-digital converter, the analog-to-digital converter is connected with the field programmable gate array, and the field programmable gate array is connected with the field programmable gate array The processor is connected with the memory; the processor includes an attitude angle calculation module, a quaternion initialization module and a quaternion update module. Use the measurement data of the temperature sensor to correct the measurement data of the three-axis accelerometer, the three-axis gyroscope and the three-axis magnetic sensor respectively, and use the corrected measurement data of the three-axis accelerometer and the three-axis magnetic sensor to calculate the initial attitude angle, and use the initial attitude Initialize the angle pair quaternion, update the time of the initialized quaternion according to the measurement data of the three-axis MEMS gyroscope, and then use the updated quaternion to calculate the attitude angle, and initialize the quaternion periodically to eliminate Accumulated error of a three-axis MEMS gyroscope.

Further, the measurement sensor is installed orthogonally to three axes of X, Y, and Z, and in each axis, the directions of the sensitive axes of the accelerometer, gyroscope and magnetic sensor are kept parallel.

Further, the measurement circuit includes an analog-to-digital converter, a field programmable gate array (FPGA), a memory, a processor and a low-pass filter, and the low-pass filter filters out the three-axis accelerometer, three-axis For high-frequency interference in the output signals of the gyroscope, three-axis magnetic sensor and a temperature sensor, select and design a filter with a low-pass cut-off frequency matching it according to the frequency bands of the accelerometer, gyroscope, magnetic sensor and temperature sensor and the drilling speed.

Further, the structure of the measurement circuit is as follows: the analog signal output by the measurement sensor is filtered out by a low-pass filter to remove high-frequency interference, and the filtered output signal of the measurement sensor is collected through an analog-to-digital converter, and the timing control of the collection is realized by FPGA At the same time, the FPGA will digitally filter the collected raw data, pack them and send them to the processor according to the communication protocol, and the processor will store the raw time data in the memory and calculate the attitude angle at the same time.

Further, the accelerometer is a MEMS accelerometer, the gyroscope is a MEMS gyroscope, and the magnetic sensor is a magnetoresistive sensor.

Further, the three-axis accelerometer, three-axis gyroscope, three-axis magnetic sensor and a temperature sensor are measured in a synchronous acquisition manner.

Further, the attitude angle includes inclination angle, azimuth angle and tool face.

Further, the device is installed in the mud channel in the center of the drill collar or installed in grooves on the surface of the drill collar.

A method for measuring the attitude of drilling tools near the drill bit while drilling, using the above-mentioned device, the method is to use the temperature sensor measurement data to respectively correct the measurement data of the three-axis accelerometer, the three-axis gyroscope and the three-axis magnetic sensor, and use the corrected three-axis The measurement data of the three-axis accelerometer and the three-axis magnetic sensor are used to calculate the attitude angle one, and the attitude angle is used to initialize a pair of quaternions, and the time of the initialized quaternion is updated according to the measurement data of the three-axis MEMS gyroscope, and then the updated quaternion is used. The final quaternion calculates the attitude angle, and periodically initializes the quaternion to eliminate the accumulated error of the three-axis MEMS gyroscope.

Further, the method further includes using the stored calibration coefficients of the accelerometer, the magnetic sensor and the gyroscope to correct the scale coefficients and installation errors of the accelerometer and the magnetic sensor.

Further, the period is 1-10 seconds, which is specifically determined according to the rotation speed of the drilling tool and the update rate of attitude data.

Beneficial technical effects of the utility model:

(1) Based on the combination of micro-inertial devices and magnetoresistive sensors, it is small in size and low in power consumption, meeting the requirements for the installation space of the near-drill attitude measurement device and the working time under battery power;

(2) Use inertial and geomagnetic integrated navigation to achieve attitude measurement, overcome the inherent defects of a single attitude measurement method (the cumulative error problem of micro-inertial devices and the interference problem of geomagnetic field measurement), and effectively improve the attitude measurement of downhole drilling tools through multi-sensor information fusion Accuracy, suitable for complex drilling measurement applications.

Description of drawings

Figure 1 is a schematic diagram of the installation of a three-axis accelerometer, a three-axis gyroscope, and a three-axis magnetic sensor;

Fig. 2 is a kind of circuit diagram of measuring device while drilling for attitude of drilling tool near the drill bit;

Fig. 3 is a flow chart of a method for measuring the attitude of a drilling tool near the drill bit while drilling.

detailed description

In order to make the purpose, technical solution and advantages of the utility model clearer, the utility model will be further described in detail below in conjunction with the accompanying drawings and embodiments. It should be understood that the specific embodiments described here are only used to explain the utility model, and are not intended to limit the utility model.

On the contrary, the utility model covers any alternatives, modifications, equivalent methods and schemes made on the spirit and scope of the utility model defined by the claims. Further, in order to make the public have a better understanding of the utility model, some specific details are described in detail in the detailed description of the utility model below. Those skilled in the art can fully understand the present invention without the description of these detailed parts.

Example 1

A device for measuring the attitude while drilling near the drill bit, including a measurement sensor and a measurement circuit, the measurement signal of the measurement sensor is transmitted to the measurement circuit, and the measurement circuit processes and calculates the signal to obtain attitude data; the measurement sensor includes a three-axis MEMS Accelerometer, three-axis MEMS gyroscope, three-axis magnetoresistive sensor and a temperature sensor, the measurement sensor adopts three-axis X, Y, Z orthogonal installation, in each axis, the sensitive axis direction of different sensors installed keep parallel. As shown in Figure 1.

The measurement circuit includes an analog-to-digital converter, a field programmable gate array (FPGA), a memory, a processor and a low-pass filter, and the low-pass filter filters out the three-axis MEMS accelerometer, the three-axis MEMS gyro high-frequency interference in the output signals of the instrument, a three-axis magneto-resistive sensor, and a temperature sensor.

The circuit structure of the device is as follows: the analog signal output by the sensor passes through a low-pass filter to filter out high-frequency interference, and a filter with a cut-off frequency matching it is designed for different sensor frequency bands and drilling speeds. At the same time, the low-pass filter before the A/D converter also plays the role of anti-aliasing filter. The filtered sensor output signal is passed through an analog-to-digital converter for data acquisition. The timing control of the acquisition is realized by the Field Programmable Gate Array (FPGA). At the same time, the FPGA digitally filters the original data collected, packs them and sends them to the ARM microprocessor according to the communication protocol, and the microprocessor stores the original time data in the FLASH. Simultaneously calculate the inclination angle, azimuth angle and tool face angle. The original data and calculation results are uploaded to the computer through the USB bus, which is convenient for processing and verification of complex algorithms. as shown in picture 2.

The memory stores calibration coefficients for the accelerometer, magnetic sensor and gyroscope.

The device is installed in the mud channel in the center of the drill collar or installed in grooves on the surface of the drill collar.

Using the device, a method for measuring the attitude of a drilling tool near the drill bit while drilling, the method specifically includes the following steps:

(1) Measure the three-axis accelerometer signal Ax, Ay, Az, the three-axis magnetoresistive sensor signal Mx, My, Mz, and the temperature sensor output value T;

(2) According to the measured value of the temperature sensor, use the stored temperature calibration coefficient to perform temperature correction on each axis of the three-axis accelerometer and the three-axis magnetic sensor;

(3) Utilize the stored triaxial accelerometer and triaxial magnetic sensor calibration coefficients to correct the triaxial accelerometer and triaxial magnetic sensor calibration coefficients and installation errors;

Accelerometer correction formula:

a _x , a _y , a _z are the acceleration values after compensation, A _x , A _y , A _z are the acceleration values of the original measurement, K ₀ and K ₁ are correction coefficients, which are read from the memory in the device attitude measurement circuit;

Magnetic sensor correction formula:

m _x , my _y , m _z are the magnetic field values after compensation, M _x , My _y , M _z are the magnetic field values before compensation, S ₀ and S ₁ are correction coefficients, which are read from the memory in the circuit of the attitude measurement device;

(4) Utilize the corrected three-axis accelerometer and three-axis magnetic sensor data to calculate the attitude angle one;

The θ is the inclination angle; φ is the tool face angle; ψ is the azimuth angle

(5) Utilize the attitude angle one to initialize the quaternion;

The q0, q1, q2 and q3 represent quaternions;

(6) Measure the three-axis gyroscope signal Ωx, Ωy, Ωz and the output signal T of the temperature sensor, and use the stored temperature calibration coefficient to perform temperature correction on each axis of the three-axis gyroscope signal according to the measured value of the temperature sensor ;

(7) Utilize the stored gyroscope calibration coefficient to correct the gyroscope scale coefficient and installation error;

ω _x , ω _y , ω _z are the angular velocity values after compensation, Ω _x , Ω _y , Ω _z are the original measured angular velocity values, W ₀ and W ₁ are correction coefficients, which are read from the memory in the device attitude measurement circuit;

(8) Use quaternions for time update, and calculate new quaternions by solving differential equations

(9) Calculate attitude angle 2 according to the new quaternion value;

θ=arcsin(2(q ₁ q ₃ -q ₀ q ₂ ))

(10) measure the next group of gyroscope data, repeat steps (7)-(9) to calculate attitude angle three;

(11) Enter step (1) after 1-10s, re-use the data of the three-axis accelerometer and the three-axis magnetic sensor to calculate the attitude angle one, and initialize the quaternion to eliminate the cumulative error of the gyroscope.

The flow chart of the near-bit drilling tool attitude measurement while drilling method is shown in Figure 3.

Claims (8)

1. A near-drill bit drilling tool attitude measurement device while drilling is characterized in that it comprises a measurement sensor and a measurement circuit, and the measurement sensor measurement signal is transmitted to the measurement circuit, and the measurement circuit processes and calculates the signal to obtain attitude data; The measurement sensors include a three-axis accelerometer, three-axis gyroscope, three-axis magnetic sensor, and a temperature sensor, and the measurement circuit includes an analog-to-digital converter, field-programmable gate array (FPGA), memory, processor, and low-pass filter ; The processor includes an attitude angle calculation module, a quaternion initialization module and a quaternion update module. 2. as claimed in claim 1, the near-drill bit attitude measuring device while drilling is characterized in that, the three-axis accelerometer, the three-axis gyroscope, and the three-axis magnetic sensor adopt X, Y, and Z three-axis orthogonal installations, In each axis, the directions of the sensitive axes of the accelerometers, gyroscopes and magnetic sensors are kept parallel. 3. as claimed in claim 1, near drill bit drilling tool attitude measuring device while drilling, it is characterized in that, the low-pass cut-off frequency of described low-pass filter is according to the frequency band and the drilling speed of accelerometer, gyroscope, magnetic sensor and temperature sensor Choose. 4. as claimed in claim 1, the near-drill drill tool attitude measuring device while drilling is characterized in that, the measurement circuit structure is as follows: the filter is connected with the measurement sensor, and the filter is connected with the analog-to-digital conversion The analog-to-digital converter is connected to the field programmable gate array, the field programmable gate array is connected to the processor, and the processor is connected to the memory. 5 . The device for measuring the attitude of drilling tools near the drill bit while drilling according to claim 1 , wherein the accelerometer is a MEMS accelerometer, the gyroscope is a MEMS gyroscope, and the magnetic sensor is a magnetoresistive sensor. 6. The device for measuring the attitude of drilling tools near the drill bit while drilling as claimed in claim 1, wherein the three-axis accelerometer, the three-axis gyroscope, the three-axis magnetic sensor and a temperature sensor adopt a synchronous acquisition method for measurement. 7. The device for measuring the attitude of the near-bit drill tool while drilling as claimed in claim 1, wherein the memory stores calibration coefficients of the accelerometer, the magnetic sensor and the gyroscope. 8. The near-bit drilling tool attitude measurement-while-drilling device according to any one of claims 1-7, wherein the attitude angle includes a dip angle, an azimuth angle and a tool face angle.