Disclosure of Invention
The present invention mainly solves the above technical problems in the prior art, and provides a signal processing system and method for torque measurement. The signal processing system and the method utilize the known frequency characteristic of the alternating current signal, and filter out noise signals outside a frequency band through a band-pass filter, a phase-locked amplifier and the like, thereby extracting weak signals capable of reflecting torque changes.
The technical problem of the invention is mainly solved by the following technical scheme:
a signal processing system for torque measurement, comprising:
the device comprises a controller, a waveform generator, an alternating current excitation amplifying circuit, a torque strain measuring bridge, a pre-amplifier, a band-pass filter, a post-amplifier and a phase-locked amplifier which are sequentially connected in series;
the bridge arm of the torque strain measurement bridge is formed by serially connecting torque strain measurement bodies which are arranged on the outer wall of the drill collar and form the same included angle with the axial direction of the drill collar.
In the optimized signal processing system for torque measurement, the output end of the phase-locked amplifier is sequentially connected with the low-pass filter, the rectifier bridge circuit, the signal acquisition circuit and the controller.
Preferably, the controller is further connected with a temperature sensor.
Preferably, the controller is connected with the MWD communication 485 protocol interface circuit.
The optimized signal processing system for torque measurement is characterized in that the torque strain measuring bodies are arranged on torque measuring sensors in a circular ring structure, and each torque measuring sensor is provided with 4 torque strain measuring bodies which are respectively arranged in a 0-degree direction, a 45-degree direction, a 135-degree direction, a 225-degree direction and a 315-degree direction relative to a drill collar shaft; a bridge arm formed by connecting the torque strain measuring bodies which are separated by 90 degrees; and taking the voltage difference of the bridge arm connection points as torque voltage.
Optimized, the signal processing system for torque measurement of the above, the model number of the waveform generator is AD 5932; the controller is a single chip microcomputer with the model number dspic33fj256mc 710A.
A signal processing method for torque measurement, comprising:
the method comprises the following steps that a controller and a waveform generator are sequentially connected in series, and an alternating current excitation amplifying circuit generates an alternating current signal and serves as an excitation signal of a torque strain measuring bridge;
the output signals of the torque strain measuring bridge are sequentially sent to the torque strain measuring bridge, and the torque signals are extracted after the processing of a pre-amplifier, a band-pass filter, a post-amplifier and a lock-in amplifier;
the bridge arm of the torque strain measurement bridge is formed by serially connecting torque strain measurement bodies which are arranged on the outer wall of the drill collar and have the same angle with the axial direction of the drill collar.
Preferably, in the signal processing method for torque measurement, the output end of the lock-in amplifier is sequentially connected to the low-pass filter, the rectifier bridge circuit, the signal acquisition circuit, and the controller.
Preferably, in the signal processing method for torque measurement, the controller is further connected with a temperature sensor.
Preferably, in the signal processing method for torque measurement, the controller is connected with the MWD communication 485 protocol interface circuit.
Therefore, the invention has the following advantages: 1. by adopting a measurement while drilling mode, the torque borne by the drilling tool can be acquired in real time, so that support is provided for quickly adjusting the parameters of the drilling tool; 2. the torque change is monitored by adopting the measuring bodies on the circular ring structures of the multiple torque measuring sensors, so that the measuring precision is improved.
Drawings
FIG. 1-1 is a schematic diagram of a device for measuring downhole torque while drilling according to the present invention;
FIGS. 1-2 are cross-sectional views of a torque measuring drill collar body along a torque sensor mounting groove;
FIG. 2-1 is a schematic diagram of a torsional strain gauge body;
FIG. 2-2 is a schematic view of a torque strain gauge mounting structure;
FIGS. 2-3 are schematic illustrations of a torque strain gauge body;
FIG. 3 is a schematic diagram of a measuring bridge configuration;
FIG. 4 is a force analysis schematic of a torque measurement ring;
FIG. 5 is a schematic diagram of the circuitry of the LWD downhole torque measurement device;
FIG. 6 is a block diagram of an AC signal excitation and torque measurement signal conditioning acquisition circuit.
In the figure, R1-45, R2-45, R3-45, R4-45, R5-45 and R6-45 are equivalent resistances of a torque measuring body in a 45-degree direction;
r1-135, R2-135, R3-135, R4-135, R5-135 and R6-135 are equivalent resistances of a torque measuring body in the 135-degree direction;
r1-225, R2-225, R3-225, R4-225, R5-225, R6-225 are equivalent resistances of the torque measuring body in the 225-degree direction;
r1-315, R2-315, R3-315, R4-315, R5-315, R6-315 are equivalent resistances of the torque measuring body in the 315-degree direction;
the torque strain measurement device comprises an MWD interface protocol circuit cabin body 1, a torque strain measurement circuit cabin body 2, a measurement drill collar body 3, a torque strain measurement body mounting cabin body 4, a battery cabin body 5, a water eye mud channel 6, a through hole (T1-T6)7, a P-type semiconductor 8, a conductive channel 9, an N-type semiconductor 10, a positioning groove 11, a TOB-4512, a TOB-13513, a TOB-22514, a TOB-31515, a torque strain measurement body 16 and a torque sensor ring 17 for preventing the torque strain measurement body.
Detailed Description
The technical scheme of the invention is further specifically described by the following embodiments and the accompanying drawings.
Example (b):
1. drill collar device structure
Referring to fig. 1-1, the present invention provides a device for measuring torque while drilling, comprising: the device comprises an underground torque measurement and measurement drill collar installation body capable of bearing petroleum drilling pressure, an array round hole for installing a torque measurement sensor, a battery cabin body, a pressure measurement circuit cabin body and an MWD interface protocol circuit cabin body.
The torque measuring sensors are arranged in an equidistant circumferential array mode in the axial direction of the drill collar body and are composed of torque measuring rings in which torque strain measuring bodies are stuck, the torque force on a dynamic parameter measuring short circuit in the drilling process of the coiled tubing can be measured by the aid of the circular ring array, measured torque force signals are sent to a measuring signal conditioning circuit to be subjected to corresponding signal processing, the torque force signals are converted into digital torque values through AD sampling, the digital torque values are transmitted to an underground MWD instrument through an MWD interface protocol circuit, and the measured torque force data are uploaded to the ground through a slurry channel of the underground MWD instrument. The measured torque force data is also saved downhole in mass storage for later data playback after tripping.
The torque strain measuring body array, the measuring signal conditioning circuit, the battery power supply circuit and the MWD interface protocol circuit of the torque measuring device are arranged on the side wall of the drill collar, the battery power supply unit connecting line and the MWD interface protocol circuit connecting line are arranged inside a water hole of the drill collar, and the drill collar body is designed in a water hole eccentric structure, so that mud can smoothly flow through a mud channel of the drill collar body. The mechanical structure design in the mud channel is to lead out the power supply battery unit connecting wire and the MWD interface protocol circuit connecting wire from the short-circuit cabin body on the side wall of the drill collar to a slip ring joint of other downhole instruments (such as the downhole MWD instruments) to ensure the communication with the other downhole instruments. Two O-shaped sealing ring structures are respectively arranged at two ends of the mechanical structure, so that the mud liquid in the mud channel can be reliably ensured not to enter a cabin body of the battery power supply single circuit, the MWD protocol interface circuit, the torque measurement sensor array and the torque measurement signal conditioning circuit.
As shown in fig. 1-1, six grooves and four installation chambers are processed on a drill collar of the downhole torque measuring device, and the circular grooves for installing the torque sensor are cylindrical. One of the four installation cabins is provided with a torque measurement signal conditioning and collecting circuit board, one is provided with an MWD interface protocol circuit, the other two are provided with a battery power supply circuit, and through holes are processed among six cylindrical grooves for connection.
In the side view of the drill collar body shown in fig. 1-1, cylindrical grooves are processed on the torque measuring drill collar body and are connected with a torque measuring signal conditioning and collecting circuit board cabin. The device is used for placing a signal output line and a signal input line of a torque strain measuring body on a torque sensor circular ring.
FIGS. 1-2 are cross-sectional views of a torque measuring collar body along a torque sensor mounting groove. In the circumferential direction of the drill collar body, 6 torque sensor mounting grooves are processed clockwise, and the interval angle of each torque sensor cylindrical mounting groove is 60 degrees. The 6 smooth torque sensor cylindrical grooves, P1 to P6, are used to mount the torque sensor rings.
In the cross section, the cylindrical grooves P1 to P6 of the torque sensor are connected with each other through holes T1 to T6 by using shielding wires, and the shielding wires connect torque strain measuring bodies on the circular rings of the torque sensor in the 6 grooves to form a sensor array for measuring the torque force borne by the drill collar body.
Each shielding wire is required to be additionally provided with a heat-shrinkable tube for protecting the shielding wire, so that the wire is prevented from being scratched by metal burrs after the drill collar body is processed. In addition, all processed the thread on every torque sensor cylindrical recess of P1 to P6, can install the metal bolt apron of joining in marriage the sealing washer, to placing the torque sensor ring, the formation mechanical protection structure of torque strain measurement body in torque sensor cylindrical recess and the recess, prevent when drilling the measurement in the pit, the invasion of the high pressure mud thick liquid in the environment to and the infiltration of the broken rock bits that the strong vibration arouses in the drilling process for torque measurement body, battery power supply circuit, MWD interface protocol circuit and torque measurement circuit normally work.
2. Torque strain measuring body
The torque strain measuring body is mainly formed by a doped silicon crystal thin strip, two ends of the silicon oxide thin strip are doped to change the conductivity of the silicon oxide thin strip, a conductive channel can be formed in the silicon crystal thin strip under the action of an external circuit voltage, when a torque force is applied to the doped silicon crystal thin strip, the doped silicon crystal thin strip generates corresponding strain, the shape of the conductive channel is changed due to the strain, the size of current flowing through the conductive channel is changed, and the whole doped silicon crystal thin strip shows resistance change to the outside. When the torque strain measuring body forms a corresponding bridge array, the resistance change of the torque strain measuring body caused by the torque strain causes different partial pressures of bridge arms of the bridge, so that the bridge outputs a voltage value corresponding to the torque strain. The main structure of the torque strain measurement body is shown in fig. 2-1. The silicon crystal film is a device with four end points, and the figure shows that trivalent element boron is doped into two ends of the silicon crystal film by using an ion implantation process to form a P-type semiconductor so as to generate holes, and the valent element phosphorus is doped into the middle of the silicon crystal film by using an ion implantation process to form an N-type semiconductor so as to generate electrons. The middle part of the silicon crystal film is formed with parasitic capacitance by metal/insulator/semiconductor structure.
The metal plate on the insulating layer is called a gate electrode G, and the electric field on the surface of the doped N-type silicon crystal can be controlled by changing the electric field intensity in the insulating layer through parasitic capacitance by applying a gate voltage on the gate. Thereby changing the width of the channel on the surface of the doped N-type silicon crystal and further changing the conductivity of the channel.
The electrodes on two sides of the silicon crystal are respectively a source electrode and a drain electrode which are formed by doped P-type semiconductor, and electrons flow into the conductive channel from the source electrode of the P-type semiconductor and flow out from the drain electrode of the P-type semiconductor under the state that the conductive channel is opened.
The silicon crystal is a doped N-type semiconductor electrode. An electron depletion layer is formed due to the permeation of the interface between the N-type semiconductor and the P-type semiconductor. So that a threshold voltage V exists between the G-pole N-type semiconductor and the S-pole P-type semiconductorTTP。
When V is added between the drain D and the source STGSAt the time of negative voltage, the N-type semiconductor surface electron depletion layer gradually becomes hole accumulation as the negative gate voltage of the gate G increases. When the gate voltage VTGS<VTTPThen, a P-type conduction channel will appear on the silicon crystal surface. The conductive channel is at a source-drain voltage VTDSUnder the action of the electric current ITDSThrough the P-type channel from the source S to the drain D.
VTGS>VTTPWith a negative voltage VTGSIncrease of silicon crystal surfaceThe accumulation of holes gradually disappears to gradually form a depletion layer. The equivalent resistance of the depletion layer is very large, so that the current passing through the drain and the source is very small, namely the reverse osmosis current between PN junctions, so that the equivalent is ITDS=0。
When the voltage applied to the source and the drain of the grid by an external circuit satisfies VTGS<=VTTPAnd VTGS-VTTP<VTDSUnder the condition, a strong conductive channel is formed on the surface of the doped N-type semiconductor silicon crystal film. The negative bias voltage V between the drain and source electrodes DSTDSHoles will be forced from the source S to the drain D through the P-type conduction channel, resulting in a current ITDSThis current can be expressed by the following equation.
In the formula ITDS-leakage current
KT' -transconductance coefficient of the device, KT′=μTP×CTOX,μTPFor hole mobility, CTOXIs a gate capacitor
WTWidth of channel
LT-channel length
VTGS-gate voltage
VTDS-source drain voltage
VTTP-turn-on voltage
Equivalent resistance R of P channel formed on surface of doped silicon crystal filmTIs composed of
The equivalent resistance R of the torque strain measurement body can be seen from the formulaTWidth W of channel formed with silicon crystal surfaceTAnd channel length LTThe relationship between them. When the torque strain gauge is elongated by the external torque, the channel width WTReduced stress and channel length LTThe stress becomes large, so that the torque strain measuring body shows the equivalent resistance RTBecomes larger. When the torque strain gauge is compressed by the external torque, the channel width WTIncreased stress and channel length LTThe stress is reduced, so the torque strain measuring body shows equivalent resistance RTAnd becomes smaller. Therefore, under the condition that the bridge voltage is stable, the voltage value output by the bridge and the torque value born by the torque strain measuring body have a corresponding relation.
3. Measuring body bridge connection structure
The six torque sensor rings placed in the cylinder grooves P1-P6 are made of the same structure and material, and beryllium copper with good elasticity is selected as the material. The surface wall of each torque sensor ring is adhered with a doped silicon crystal torque strain measuring body, as shown in figure 2-2. Each torque sensor ring has 4 such measuring bodies mounted thereon. The torque strain measuring bodies are clockwise installed along the direction of the axis of the drill collar, 4 torque strain measuring bodies are installed on each torque sensor circular ring, the four measuring bodies are respectively located at the positions which are different by 45 degrees, 135 degrees, 225 degrees and 315 degrees relative to the direction of 0 degree of the drill collar shaft, and the bridge structure formed by the four measuring bodies is used for detecting the torque force loaded on the drill collar body to cause the deformation of the torque sensor circular ring. The 0-degree directions of the torque sensor rings in the cylinder grooves P1 to P6 are all parallel to the collar axis direction, and through holes T1 to T6 are machined in each cylinder groove.
The measuring bodies on the torque measuring circular ring in the cylindrical groove are connected by using a lead wire, and a measuring bridge structure is formed. The lead wires are connected to the corresponding measuring bodies through the through holes T1 to T6 in the grooves of each cylinder in the manner shown in fig. 3.
Torque strain measuring bodies with the same angle on the torque measuring rings in the 6 grooves are connected to a bridge arm, and taking the torque measuring ring in the groove of the P1 cylinder as an example, as shown in fig. 3, the torque strain measuring bodies TOB _45 on the ring and the torque strain measuring bodies TOB _45 in the grooves P2, P3, P4, P5 and P6 form a group of torque measuring bridge arms.
According to the design, four groups of torque strain measuring arms can be constructed by the torque strain measuring bodies in four directions of the bridge, and two torque strain measuring arms which are separated by 90 degrees are connected together. A connection line between the TOB _45 torque strain measurement bridge arm and the TOB _135 torque strain measurement bridge arm may be led out as a terminal UOUT1 of the torque measurement output wire, and a connection line between the TOB _225 torque strain measurement bridge arm and the TOB _315 torque strain measurement bridge arm may be led out as the other terminal UOUT2 of the torque measurement wire.
The voltage difference between the output voltages of UOUT1 and UOUT2 reflects the amount of change in the torque experienced by the drill collar body. The connection between the torque strain measurement bridge arm of TOB _45 and the torque strain measurement bridge arm of TOB _315 leads to a terminal UIN1 as a signal input to the torque measurement bridge. The connection between the torque strain measurement bridge arm of TOB _135 and the torque strain measurement bridge arm of TOB _225 leads to a further terminal UIN2 as a signal input to the torque measurement bridge. A constant voltage signal or a fixed frequency sine wave signal may be added between UIN1 and UIN2 as a source of excitation input signals for the bridge.
Force analysis of the torque measurement rings is shown in fig. 4. When the drill collar body receives the action of torque force, the 6 cylindrical grooves processed on the drill collar can deform under the action of the torque force. At the moment, the measuring bodies in the TOB _135 torque strain measuring bridge arm and the TOB _315 torque strain measuring bridge arm are subjected to extension deformation under the action of tensile force, and the measuring bodies in the TOB _45 torque strain measuring bridge arm and the TOB _225 torque strain measuring bridge arm are subjected to contraction deformation under the action of extrusion force. Therefore, due to the voltage division effect of four bridge arms in the bridge circuit, the formed electric balance is broken, a voltage signal related to torque strain is generated between the UOUT1 and the UOUT2, and the voltage signal is subjected to signal conditioning, is collected and reflects the variation of the torque force received by the drill collar body through calibration.
4. Signal processing
As shown in FIG. 5, when the drill collar receives a torsional force influence, a torque sensor bridge array arranged in a cylindrical groove of the drill collar also receives the torsional force influence, and corresponding voltage output is generated. The voltage output signal is amplified and filtered, then transmitted to an AD sampling circuit for analog-to-digital conversion and corresponding digital signal processing, finally converted into a torque value, stored in a downhole memory, sent to an MWD instrument through an MWD interface protocol circuit, and transmitted to a ground receiving device through the MWD instrument and a mud channel.
And the signal conditioning circuit amplifies and filters the signal output by the torque measuring ring. As shown in fig. 3, a dc voltage signal or an ac signal can be applied between the torque measuring bridge signal inputs UIN1 and UIN2, the selection of the input signal type being switchable by means of a signal selection circuit. The signal switching design is that when the torsion borne by the drill collar is large, the voltage signal between the output end UOUT1 of the torque measuring ring and the output end UOUT2 is large, so that the signal-to-noise ratio is high, the amplification factor of a direct measuring signal can be set to be low, and the torsion borne by the drill collar can be reflected by the signal through simple processing and calibration. However, when the torsion borne by the drill collar is small, the voltage signal between the output end UOUT1 of the torque measuring ring and the output end UOUT2 is very weak, and the signal-to-noise ratio is poor, so that the effective signal of the reaction torque is difficult to accurately measure by singly increasing the amplification factor. At this time, if an ac signal is input between UIN1 and UIN2, since the ac signal has a known frequency characteristic, a noise signal outside the frequency band can be filtered by processing such as a band pass filter and a lock-in amplifier, and a weak signal that can reflect a change in torque can be extracted. Fig. 6 shows a block diagram of the ac signal excitation and torque measurement signal conditioning and acquisition circuit.
The DDS chip AD5932 is controlled by a singlechip dspic33fj256mc710A to realize the DDS chip AD 5932. The DDS chip provides a scheme for generating analog waveform models with adjustable frequency. Usually, the digital signal is converted by time in digital form, and then the DAC performs digital-to-analog conversion to generate a sine wave voltage signal with a desired frequency. Because the operation on the DDS device is based on digital operation, the frequency of the output signal can be finely adjusted, and the adjustment range of the frequency of the signal output is large. Since the DDS device can be programmed and controlled through the SPI interface and has low power consumption, the DDS device can be selected as an alternating current frequency signal source of the torque measuring bridge. The DDS of the AD5932 can be programmed through a high-speed Serial Peripheral Interface (SPI), and only the single chip microcomputer is required to be programmed through the SPI. The AD5932 is able to produce a sine wave waveform below 400KHz with a clock based on 25 MHz. The signal can generate sine wave AC excitation signal with stronger excitation current through AC excitation amplifying circuit, and the sine wave AC excitation signal is added between UIN1 and UIN2 to provide AC excitation source of bridge.
Since the output signal of the bridge circuit (i.e. the voltage signal between UOUT1 and UOUT 2) on the torque measurement ring is very weak and easily interfered by external noise, the pre-stage amplification circuit should be accessed first. The amplification gain and noise figure of the preamplifier determine to a large extent the overall noise level of the system. It is critical to reduce the noise figure of the first stage amplifier to reduce the overall noise figure of the overall signal conditioning circuit. The front-stage amplifier circuit is formed by a variable gain and high performance instrumentation amplifier AD620 of the Asia-Deno semiconductor company. The AD620 has high common mode rejection ratio for frequency signals in a bandwidth, and can suppress noise interference in the bandwidth and harmonic waves generated by a signal line, so that common mode noise signals can be well suppressed in a pre-stage amplifying circuit formed by the AD620, differential mode torque voltage signals can be effectively amplified, and the torque voltage signal measurement has the characteristics of high gain precision, low offset drift, high common mode rejection ratio and the like.
The output signal of the measuring body bridge circuit on the torque measuring ring is amplified by the instrumentation amplifier AD620, passes through the RC band-pass frequency-selective network, and is input to the lock-in amplifier AD630, as shown in fig. 6. The phase-locked amplifier is a frequency-selecting amplifier based on correlation operation, and can separate weak torque voltage signals with specific frequency from noise signals through correlation processing.
The working principle of frequency selection is as follows: the torque voltage signal which is superimposed with noise interference components and contains fixed frequency is input to a phase-locked amplifier AD630, and the amplifier takes another sinusoidal voltage signal which has stable voltage amplitude and identical frequency with the torque voltage signal as a reference input signal and carries out cross-correlation processing through a hardware structure in a chip.
The noise interference portion in the torque voltage signal does not have cross-correlation in the frequency domain with the reference voltage signal. And is strongly suppressed in the cross-correlation processing link, so that signals with different frequencies from the torque voltage signal can be attenuated through the phase-locked amplification AD 630. Therefore, the signal-to-noise ratio of the torque voltage signal is improved, and a premise is provided for realizing accurate measurement of the torque voltage signal. In the circuit, a frequency selection circuit is formed by adopting a phase-locked amplifier AD630 of the Asia-Deno semiconductor company. 400HZ sine wave signals generated by the DDS chip AD5932 are input to the chip through an SELB pin of the AD630, and are subjected to cross-correlation operation with torque voltage signals which are output by a measuring body bridge circuit on the torque measuring circular ring and amplified by the AD620 in the chip. The calculated torque voltage signal is output through a VOUT pin. The signal is converted into a direct current voltage signal through a 20HZ cut-off frequency low-pass filter circuit and a rectifier bridge circuit in the figure 6, and the change of the signal size reflects the change of the torque force carried on the torque measuring ring.
The torque voltage signals which are processed in a cross-correlation mode by the AD630 and subjected to low-pass filtering rectification are output to a single chip microcomputer circuit board, the signals are collected by an analog-to-digital conversion channel of the single chip microcomputer, the underground temperature is measured by an external temperature measurement chip, the collected torque signals and the temperature are stored on an external storage chip, and a command sent by the main MWD is correspondingly processed through a communication circuit.
5. Signal calibration
Because the underground torque measuring device while drilling works in an underground high-temperature environment, different environmental temperatures can affect the measurement on the torque measuring ring, and the device needs to be calibrated. Different torque forces generated by a large-scale torque calibration device are loaded on a drill collar body of the while-drilling downhole torque measurement device. Therefore, the underground torque measurement while drilling device can measure corresponding voltage values according to different torque values. Substituting torque values and corresponding voltage values into a polynomial equation
Where X is the output voltage value of the torque measuring device while drilling, and y is the actual value of the torque force loaded by the torque calibration device. In fact, as long as the response of the sensor can be expressed as a monotone continuous function, it can be approximated to an arbitrary precision by a polynomial function, and therefore the above equation can be generally established. a isTiCan be calculated by using Least Mean Square (LMS) method according to experimental data, and it should be noted that for the polynomial of degree N, at least N +1 data points are needed for calculation. In practical applications, the value of N should not be too large, and generally it is enough to be 4 or less, and the more data points, the better, where N is 4. Then, considering the influence of the temperature, the ai in the above formula will change at different temperatures. That is to say aTiIs a function of the temperature t. Similarly, a polynomial function can also be used to approximate:
final torque force yTIt can be expressed as:
as long as b is used hereinTijThe calibration work of torque measurement under different temperature environments can be completed after the determination, and the above formula can also be expressed in a matrix form.
T=(1,t,..........tM)
yT=T*BT*X
The calibration algorithm finally obtains a set of calibration coefficients B. When the underground torque measuring device works in a well while drilling mode, a temperature value t of a drill collar body is measured through a temperature sensor, and then the temperature value is brought into a formula:
b in the formulaTijThat is, after calibration is complete, the resulting calibration coefficients, which when substituted into the above formula, will yield coefficients ai. At the moment, the device for measuring the underground torque while drilling during underground work measures the voltage value X measured from the torque measuring ring and the coefficient a generated by the above formulaTiThe formula is substituted:
the y obtained by the formula through calculation is the torque force borne by the drill collar body of the underground torque measurement while drilling device working underground at the moment.
The specific embodiments described herein are merely illustrative of the spirit of the invention. Various modifications or additions may be made to the described embodiments or alternatives may be employed by those skilled in the art without departing from the spirit or ambit of the invention as defined in the appended claims.