Azimuthal acoustic logging while drilling apparatus and measurement method

Abstract

An azimuthal acoustic LWD apparatus is sequentially provided with a centralizer, a transmitting circuit, transmitting transducers, an acoustic insulator, a receiving transducer array, ultrasonic transducers and a receiving circuit on a drill collar. The azimuthal acoustic LWD apparatus is capable of operating in a dipole mode or a unipole mode, to cover all the sectors around a wellbore by adopting a fixed time interval measurement mode or an alternating time interval measurement mode according to a relationship of an interval between measurement times and a rotation speed of the apparatus, thereby achieving azimuthal acoustic LWD. This apparatus overcomes problems that the fixed time interval measurement mode may not cover all the sectors and further may not achieve azimuthal acoustic imaging in a case where the rotation speed and the interval between measurement times are under certain conditions.

Claims

1. An azimuthal acoustic LWD apparatus, comprising a centralizer, a transmitting circuit, transmitting transducers, an acoustic insulator, a receiving transducer array, ultrasonic transducers and a receiving circuit sequentially disposed on a drill collar; wherein the receiving circuit comprises an azimuth measurement module, the azimuth measurement module measures a magnetic toolface angle by adopting a dual-axis magnetic sensor, and the measured magnetic toolface angle is used to determine a current rotation angle of the azimuthal acoustic LWD apparatus; two axial directions of the dual-axis magnetic sensor are orthogonal to each other, one of which is in a radial direction of the azimuthal acoustic LWD apparatus, and is in the same straight line as the transmitting transducers, and the other axial direction is in a tangential direction of the azimuthal acoustic LWD apparatus; wherein the receiving circuit processes time series data measured in an axial direction of the dual-axis magnetic sensor by using a Fast Fourier Transform, and extracts frequency information for obtaining a rotation speed of the azimuthal acoustic LWD apparatus; and wherein the ultrasonic transducers are configured to measure a wellbore diameter, and a measured result of the wellbore diameter is used to determine a current position of the azimuthal acoustic LWD apparatus in a wellbore in combination with the magnetic toolface angle measured by the azimuth measurement module, and further realizes eccentricity correction and quality control of measured data.

2. The azimuthal acoustic LWD apparatus according to claim 1, wherein there are two transmitting transducers, which are oppositely installed at 180 degrees apart around the drill collar, and the transmitting transducers are capable of operating in a dipole mode or a unipole mode; the receiving transducer array comprises a plurality of sets of receiving transducers arranged at equal intervals in an axial direction of the drill collar, each set of receiving transducers comprises two receiving transducers that are oppositely installed at 180 degrees apart around the drill collar; the receiving transducers in the receiving transducer array are in a straight line along the axial direction of the drill collar as the transmitting transducers; and there are three ultrasonic transducers, which are installed at 120 degrees apart around the drill collar, wherein one ultrasonic transducer is in the same straight line along the axial direction of the drill collar as the transmitting transducers and the receiving transducers.

3. The azimuthal acoustic LWD apparatus according to claim 1, wherein the transmitting circuit is installed on the wall of the drill collar in a grooving manner and arranged apart from the transmitting transducers along the axial direction of the drill collar, so that a propagation path of acoustic waves between the transmitting transducers and the receiving transducer array does not pass through a transmitting circuit installation structure, which prevents the transmitting circuit installation structure from affecting a radiated acoustic field and avoids causing signal distortion.

4. The azimuthal acoustic LWD apparatus according to claim 2, wherein the receiving transducer array comprises 6 or 8 sets of receiving transducers arranged at equal intervals along the axial direction of the drill collar; in the receiving transducer array, the receiving transducers closest to the transmitting transducers are the first set of receiving transducers, and a distance between the first set of receiving transducers and the transmitting transducers is called a source spacing, and the source spacing is 2 m to 4 m; and in the receiving transducer array, a distance between two adjacent sets of receiving transducers in the axial direction is called a spacing, and the spacing is 15 cm to 30 cm.

5. The azimuthal acoustic LWD apparatus according to claim 1, wherein the receiving circuit is respectively connected with the receiving transducer array and the ultrasonic transducers; the receiving circuit is configured to synchronously sample acoustic signals picked up by the plurality of sets of receiving transducers, and obtain compressional and shear wave velocities by a multi-channel correlation processing algorithm; and the receiving circuit is capable of exciting the three ultrasonic transducers simultaneously and measuring echo signals to calculate the wellbore diameter.

6. The azimuthal acoustic LWD apparatus according to claim 1, wherein the receiving circuit is installed on the wall of the drill collar in a grooving manner and arranged apart from the receiving transducer array in the axial direction of the drill collar, so that a propagation path of acoustic waves between the transmitting transducers and the receiving transducer array does not pass through a receiving circuit installation structure, which prevents the receiving circuit installation structure from affecting an acoustic field and avoids causing signal distortion.

7. A measurement method for azimuthal acoustic LWD, wherein, when an azimuthal acoustic LWD apparatus operates in a unipole measurement mode or a dipole measurement mode, the azimuthal acoustic LWD apparatus rotates with a drill tool, to cover all the sectors around a wellbore by adopting a fixed time interval measurement mode or an alternating time interval measurement mode according to a relationship of a measurement time interval and a rotation speed of the azimuthal acoustic LWD apparatus; wherein, when m1 and Pn; or when m<1 and P.sub.0n, and the fixed time interval measurement mode is adopted, the collected data cover all the sectors around the wellbore; when m1 and P<n; or when m<1 and P.sub.0<n, and the fixed time interval measurement mode is adopted, the collected data do not cover all the sectors around the wellbore, and, when the alternating time interval measurement mode is adopted, the collected data cover all the sectors around the wellbore; wherein m represents the number of measurements when the azimuthal acoustic LWD apparatus completes one revolution, $m=\frac{T}{t}=\frac{60}{Rt},$ T represents time taken by completing one revolution by the azimuthal acoustic LWD apparatus, t represents an interval time between two adjacent measurement, and R represents a rotation speed of the azimuthal acoustic LWD apparatus in revolutions per minute; let $m=\frac{P}{Q},$ wherein P/Q represents an irreducible fraction, P and Q are relatively prime, meaning that the azimuthal acoustic LWD apparatus completes Q revolutions, and a total of P measurements are completed; and n represents a number of all the sectors around the wellbore; when m1, that is, PQ, the time T is greater than or equal to the interval t, and at least one measurement is performed for every revolution, and the measured azimuth interval is 360/P; data is measured for P times within Q revolutions; and when m<1, that is, P<Q, the time T is less than the interval t, let e=1/m=Q/P=N+Q.sub.0/P.sub.0, wherein N represents an integer part, which is a non-zero natural number, Q.sub.0<P.sub.0 is an irreducible fraction, Q.sub.0<P.sub.0, which is equivalent to a case where there is no measured data when the apparatus completes N revolutions, and then data is measured for P.sub.0 times after Q.sub.0 revolutions.

8. The measurement method for azimuthal acoustic LWD according to claim 7, wherein the alternating time interval measurement mode comprises two measurement processes, firstly, a first measurement is performed at a first interval t, the measurement times are T.sub.m; a second measurement is performed at a second interval t.sub.1, and the measurement times are also T.sub.m; and one azimuth measurement is completed within 2T.sub.m; wherein the second interval t.sub.1 is determined according to the first interval t; and the measurement times T.sub.m are determined according to the first interval t, the second interval t.sub.1, and a time t.sub.2 required for one measurement from the start of transmitting to the end of receiving.

9. The measurement method for azimuthal acoustic LWD according to claim 8, wherein a method for determining the first interval t is as follows: the first interval t is selected according to impulse discharge characteristics of an acoustic transducer exciting circuit and an average power of the circuit, wherein t is greater than 0.1s.

10. The measurement method for azimuthal acoustic LWD according to claim 8, wherein when m1, PQ, and P<n, a method for determining the second interval t.sub.1 according to the first interval t is as follows: in a second measurement process, the number m.sub.1 of measurements when the azimuthal acoustic LWD apparatus completes one revolution is as follows: $m_1=\frac{P_1}{Q_1}=\frac{60}{R{t}_1},$ wherein P.sub.1/Q.sub.1 is an irreducible fraction, P.sub.1 and Q.sub.1 are relatively prime, meaning that in the second measurement process, the azimuthal acoustic LWD apparatus completes Q.sub.1 revolutions, and a total of P.sub.1 measurements are completed; according to $m=\frac{P}{Q}=\frac{60}{Rt},$ it is derived that: $\frac{P_1}{Q_1}=\frac{t}{t_1}\frac{P}{Q},$ let P.sub.1/Q.sub.1>1, P.sub.1>n, so that the second measurement meets a requirement of covering all the sectors around the wellbore; because the values of the first interval t and the P/Q in the first measurement are known, the obtained second interval t.sub.1 meets the following condition: $t1<t\frac{P}{Q},$ and meets a requirement that P.sub.1 and Q.sub.1 are relatively prime, wherein P.sub.1>n; when m<1, that is, P<Q, and P.sub.0<n, a method for determining the second interval t.sub.1 according to the first interval t is as follows: when m<1, that is, when P<Q, e=1/m=Q/P=N+Q.sub.0/P.sub.0, a case where there is no measured data when the azimuthal acoustic LWD apparatus completes N revolutions is ignored, which may be converted into the following form: $m_0=\frac{P_0}{Q_0},$ wherein Q.sub.0<P.sub.0; in the second measurement process, the number m.sub.1 of measurements when the azimuthal acoustic LWD apparatus completes one revolution is as follows: $m_1=\frac{P_1}{Q_1}=\frac{60}{R{t}_1},$ wherein P.sub.1/Q.sub.1 represents an irreducible fraction, P.sub.1 and Q.sub.1 are relatively prime, meaning that in the second measurement process, the azimuthal acoustic LWD apparatus completes Q.sub.1 revolutions, and a total of P.sub.1 measurements are completed; according to $m_0=\frac{P_0}{Q_0}=\frac{60}{Rt},$ it is derived that: $\frac{P_1}{Q_1}=\frac{t}{t_1}\frac{P_0}{Q_0};$ let P.sub.1/Q.sub.1>1, P.sub.1>n; because values of the first interval t and the P.sub.0/Q.sub.0 in the first measurement are known, the obtained second interval t.sub.1 meets the following condition: $t1<t\frac{P_0}{Q_0},$ and meets a requirement that P.sub.1 and Q.sub.1 are relatively prime, wherein P.sub.1>n.

11. The measurement method for azimuthal acoustic LWD according to claim 8, wherein a method for determining the time t.sub.2 required for one measurement from the start of transmitting to the end of receiving is as follows: the time t.sub.2 is determined according to a measured source spacing and a range of wave velocities measured by the azimuthal acoustic LWD apparatus, $t_2\frac{L_{\max }}{V_{\min }},$ wherein L.sub.max represents a distance between the transmitting transducers and the farthest receiving transducer array, and V.sub.min represents a minimal acoustic wave velocities which can be measured by the azimuthal acoustic LWD apparatus.

12. The measurement method for azimuthal acoustic LWD according to claim 8, wherein in order to ensure that n sectors have no vacant points throughout a sampling process, the measurement times T.sub.m must meet: $T_m\frac{\left(t-2t_2\right)t}{\left(t_1-t\right)}.$

13. The measurement method for azimuthal acoustic LWD according to claim 7, wherein the number n of all the sectors around the wellbore is 8, 16, or 32.

14. The measurement method for azimuthal acoustic LWD according to claim 8, wherein the number n of all the sectors around the wellbore is 8, 16, or 32.

15. The measurement method for azimuthal acoustic LWD according to claim 9, wherein the number n of all the sectors around the wellbore is 8, 16, or 32.

16. The measurement method for azimuthal acoustic LWD according to claim 10, wherein the number n of all the sectors around the wellbore is 8, 16, or 32.

17. The measurement method for azimuthal acoustic LWD according to claim 11, wherein the number n of all the sectors around the wellbore is 8, 16, or 32.

18. The measurement method for azimuthal acoustic LWD according to claim 12, wherein the number n of all the sectors around the wellbore is 8, 16, or 32.

Description

BRIEF DESCRIPTION OF DRAWINGS

(1) FIG. 1 is a schematic diagram showing a structure of an azimuthal acoustic LWD apparatus according to an embodiment of the present invention;

(2) FIG. 2 is a schematic diagram of installation of transmitting transducers in an azimuthal acoustic LWD apparatus according to an embodiment of the present invention;

(3) FIG. 3 is a schematic diagram showing a dipole mode of transmitting transducers in an azimuthal acoustic LWD apparatus according to an embodiment of the present invention;

(4) FIG. 4 is a schematic diagram showing a unipole mode of transmitting transducers in an azimuthal acoustic LWD apparatus according to an embodiment of the present invention;

(5) FIG. 5 is a schematic diagram of installation of receiving transducers in an azimuthal acoustic LWD apparatus according to an embodiment of the present invention;

(6) FIG. 6 is a schematic diagram of installation of ultrasonic transducers in an azimuthal acoustic LWD apparatus according to an embodiment of the present invention;

(7) FIG. 7 is a schematic diagram of installation of a dual-axis magnetic sensor (azimuth measurement module) in an azimuthal acoustic LWD apparatus according to an embodiment of the present invention;

(8) FIG. 8 is a schematic diagram of sector allocation of measured results for azimuthal acoustic LWD according to an embodiment of the present invention (taking 16 sectors as an example);

(9) FIG. 9 is a sector coverage diagram of azimuth measurement data when m1 and P16 according to an embodiment of the present invention;

(10) FIG. 10 is a sector coverage diagram of azimuth measurement data when m1 and P<16 according to an embodiment of the present invention;

(11) FIG. 11 is a sector coverage diagram of azimuth measurement data when m<1 and P.sub.016 according to an embodiment of the present invention;

(12) FIG. 12 is a sector coverage diagram of azimuth measurement data when m<1 and P.sub.0<16 according to an embodiment of the present invention;

(13) FIG. 13 is a schematic diagram showing an alternating time interval measurement mode according to an embodiment of the present invention;

(14) FIG. 14 is a flow diagram showing an alternating time interval measurement mode according to an embodiment of the present invention;

REFERENCE NUMERALS

(15) 1. centralizer; 2. transmitting circuit; 3. transmitting transducers; 4. acoustic insulator; 5. receiving transducer array; 6. ultrasonic transducers; 7. receiving circuit; 8. mud channel; and 9. drill collar.

DETAILED DESCRIPTION

(16) In order to make objectives, technical solutions and advantages of the present invention be clearer, the present invention will be further described in detail below in conjunction with accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present invention and are not intended to limit the present invention.

(17) Rather, the present invention encompasses any alternatives, modifications, and equivalent methods and solutions of the present invention as defined by appended claims and made within the spirit and scope of the present invention. Further, in order to provide the public with a better understanding of the present invention, some specific details are described in detail in the following detailed description of the present invention. The present invention may be fully understood by those skilled in the art without a description of these details.

(18) The embodiments of the present invention provide an azimuthal acoustic LWD apparatus. As shown in FIG. 1, a centralizer 1, a transmitting circuit 2, transmitting transducers 3, a acoustic insulator 4, a receiving transducer array 5, ultrasonic transducers 6 and a receiving circuit 7 are sequentially disposed on the drill collar 9, wherein the acoustic insulator 4 is located between the transmitting transducers 3 and the receiving transducer array 5 for attenuating direct waves propagating along the drill collar. The centralizer of the azimuthal acoustic LWD apparatus is disposed on one side of a transmitting acoustic source. In this embodiment, all of the above components are installed on one drill collar, and a cylindrical mud channel 8 is disposed in the middle of the drill collar.

(19) In a specific implementation of the embodiment, there are two transmitting transducers, and as shown in FIG. 2, the two transmitting transducers (T1 and T2) are oppositely installed at 180 degrees apart around the drill collar. The transmitting transducers convert high-voltage electrical signals generated by the transmitting circuit into acoustic wave signals, and transmit them in a direction vertical to the wall of a wellbore to a formation. The transmitting transducers is capable of operating in a dipole mode or a unipole mode; two transducers are simultaneously used in the dipole mode (as shown in FIG. 3), and polarities of the pulse excitation signals applied by the two transducers are opposite. A single transmit transducer is used when operating in the unipole mode (as shown in FIG. 4).

(20) In the embodiment of the present invention, the transmitting circuit is respectively connected with the two transmitting transducers, and the transmitting circuit generates two high-voltage pulse signals, and a voltage is adjustable within a range of 200V to 2000V for exciting the transmitting transducers; and the transmitting transducers have an operating frequency range of 2 kHz to 15 kHz. The transmitting circuit is installed on the wall of the drill collar in a grooving manner and arranged apart from the transmitting transducers in the axial direction of the drill collar, so that a propagation path of acoustic waves between the transmitting transducers and the receiving transducer array does not pass through a transmitting circuit installation structure, which prevents the transmitting circuit installation structure from affecting a radiated acoustic field and avoids causing signal distortion.

(21) The receiving transducer array includes a plurality of sets of receiving transducers arranged at equal intervals in the axial direction of the drill collar, each set of receiving transducers includes two receiving transducers that are oppositely installed at 180 degrees apart around the drill collar (as shown in FIGS. 5, R1 and R2 are two receiving transducers that are oppositely installed at 180 degrees apart around the drill collar). Preferably, in a particular implementation of the present invention, the receiving transducer array includes 6 sets or 8 sets of receiving transducers arranged at equal intervals in the axial direction of the drill collar. The receiving transducers in the receiving transducer array are in a straight line along the axial direction of the drill collar as the transmitting transducers; and a direction of receiving the signals is vertical to the wall of the wellbore, for converting acoustic signals into electric signals. Arranging the plurality of sets of receiving transducers at equal intervals aims at processing a time difference of compressional waves and shear waves by adopting a multi-channel correlation processing algorithm, wherein the multi-channel correlation processing algorithm is a conventional technology in the art, and can be implemented by those skilled in the art, which will be omitted here. The present invention does not involve the improvement in the multi-channel correlation processing algorithm.

(22) In the receiving transducer array, the receiving transducers closest to the transmitting transducers are the first set of receiving transducers, and a distance between the first set of receiving transducers and the transmitting transducers is called a source spacing, and the source spacing is 2 m to 4 m; the source spacing cannot be too short, otherwise, it is not conducive to separation of various waveforms; however, in view of the attenuation of acoustic waves in a slow formation, the source spacing cannot be too large.

(23) In the receiving transducer array, a distance between two adjacent sets of receiving transducers in the axial direction is called a spacing, and the spacing is 15 cm to 30 cm. The spacing cannot be too large, to avoid spatial aliasing and attenuation; and the spacing cannot be too small, otherwise, it will affect the multi-channel correlation processing algorithm.

(24) The ultrasonic transducers are configured to measure a borehole diameter, there are three ultrasonic transducers, which are installed at 120 degrees apart around the drill collar, wherein one ultrasonic transducer is in the same straight line along the axial direction of the drill collar as the transmitting transducers and the receiving transducers (as shown in FIG. 6, S1, S2 and S2 are three ultrasonic transducers installed at 120 degrees apart around the drill collar).

(25) The receiving circuit is respectively connected with the receiving transducer array and the ultrasonic transducers; the receiving circuit is configured to synchronously sample acoustic signals picked up by the plurality of sets of receiving transducers, and obtain compressional and shear wave velocities by a multi-channel correlation processing algorithm; and the receiving circuit is capable of exciting the three ultrasonic transducers simultaneously and measuring echo signals to calculate a measured result of the borehole diameter.

(26) The receiving circuit includes a signal conditioning circuit, an analog-to-digital conversion circuit, a power supply, a processor, a memory, a control unit and an azimuth measurement module. The azimuth measurement module measures a magnetic toolface angle by adopting a dual-axis magnetic sensor; the measured magnetic toolface angle is used to determine a current rotation angle of the azimuthal acoustic LWD apparatus; as shown in FIG. 7, two axial directions of the dual-axis magnetic sensor are orthogonal to each other, one of which is in a radial direction of the azimuthal acoustic LWD apparatus, and is in the same straight line as the transmitting transducers, and the other axial direction is in a tangential direction of the azimuthal acoustic LWD apparatus, wherein the signal conditioning circuit, the analog-to-digital conversion circuit, the power supply, the processor, the memory and the control unit are all conventional technologies in the art, which can be fully implemented by those skilled in the art, and will be omitted here. The present invention does not involve the improvements in the signal conditioning circuit, the analog-to-digital conversion circuit, the power supply, the processor, the memory and the control unit.

(27) The receiving circuit processes magnetic field time series data measured in an axial direction of the dual-axis magnetic sensor by using a Fast Fourier Transform, and extracts frequency information for obtaining a rotation speed of the azimuthal acoustic LWD apparatus.

(28) The measured result of the borehole diameter of the receiving circuit is used to determine a current position of the azimuthal acoustic LWD apparatus in the wellbore in combination with the magnetic toolface angle measured by the azimuth measurement module, and further realize eccentricity correction and quality control of acoustic measured data.

(29) The receiving circuit is installed on the wall of the drill collar and arranged apart from the receiving transducer array along the axial direction of the drill collar, so that a propagation path of acoustic waves between the transmitting transducers and the receiving transducer array does not pass through a receiving circuit installation structure, which prevents the receiving circuit installation structure from affecting a radiated acoustic field and avoids causing signal distortion.

(30) When the azimuthal acoustic LWD apparatus rotates with a drill tool, the apparatus operates in a unipole mode or a dipole mode, and transmits waveforms at a fixed time interval; the receiving circuit records the waveforms at the same time interval; meanwhile, an azimuth (i.e., the magnetic toolface angle) of each measurement is recorded; and data is respectively stored in n sectors (in this embodiment, by taking 16 sectors as an example, each sector has an angle of 22.5 degrees, in other alternatives, the number of sectors may be set according to the actual situation) according to a current toolface angle value. Data measured in each sector for multiple times is stacked, so that the signal-to-noise ratio is improved. Such an azimuth coverage depends on the rotation speed of the azimuthal acoustic LWD apparatus and the interval between measurement times. The number n of all the sectors around the wellbore is 2.sup.k, k is equal to 2, 3, 4, 5 or 6; preferably, k is equal to 3, 4, or 5, i.e. n is equal to 8, 16 or 32. FIG. 8 is a schematic diagram of sector allocation of measured results for azimuthal acoustic LWD (in this embodiment, taking 16 sectors as an example).

(31) R represents a rotation speed of the azimuthal acoustic LWD apparatus in r/min, and t represents an interval time between two adjacent measurements in s,

(32) T represents time taken by completing one revolution by the azimuthal acoustic LWD apparatus (in s),

(33) $\begin{array}{cc}T=\frac{60}{R}& \left(1\right)\end{array}$

(34) m represents the number of measurements when the azimuthal acoustic LWD apparatus completes one revolution,

(35) $\begin{array}{cc}m=\frac{T}{t}=\frac{60}{Rt}& \left(2\right)\end{array}$

(36) $\mathrm{let}m=\frac{P}{Q},$
P/Q represents an irreducible fraction (P and Q are relatively prime), meaning that the azimuthal acoustic LWD apparatus completes Q revolutions, and a total of P measurements are completed.

(37) By taking 16 sectors as an example, there are two cases for discussion:

(38) (1) when m1, that is, PQ, the time used by completing one revolution by the azimuthal acoustic LWD apparatus is greater than or equal to an interval t and at least one measurement is performed for every revolution, and the measured azimuth interval is 360/P; and data starts to repeat after P measurements (within Q revolutions). Under such conditions, there are two cases for discussion:

(39) 1) when P16, each sector has at least one data coverage, and can achieve 16-sector azimuthal imaging. As shown in FIG. 9, when P=16, each sector has one measurement point;

(40) 2) when P<16, each sector cannot ensure one data coverage and may not achieve 16-sector azimuthal imaging. As shown in FIG. 10, when P=8, every two sectors have one measurement point;

(41) when m<1, that is, P<Q, the time required by completing one revolution is less than the interval, each revolution may not ensure that there is one measurement point (there are measurement points every other revolutions). Let e=1/m=Q/P, meaning that within the interval t, the azimuthal acoustic LWD apparatus completes e revolutions.

(42) Since Q/P is an improper fraction (the numerator is greater than the denominator), it is transformed into a mixed fraction form: N+Q.sub.0/P.sub.0, wherein N represents an integer part, which is a non-zero natural number, and Q.sub.0<P.sub.0 represents a proper fraction (Q.sub.0<P.sub.0), which is equivalent to a case where there is no measured data when the azimuthal acoustic LWD apparatus completes N revolutions, and the data is measured for P.sub.0 times after Q.sub.0 revolutions, and then repeated. When that the case where there is no measured data when the azimuthal acoustic LWD apparatus completes N revolutions is ignored, this is similar to a case of m1 discussed above. Under such conditions, there are two cases for discussion:

(43) 1) when P.sub.016, each sector has at least one data coverage, and can achieve 16-sector azimuthal imaging. As shown in FIG. 11, when P.sub.0=17, each sector has one measurement point;

(44) 2) when P.sub.0<16, each sector cannot ensure one data coverage and may not achieve 16-sector azimuthal imaging. As shown in FIG. 12, when P.sub.0=15, the 16th sector has no data;

(45) It may be known from the above analysis, when there is a specific relationship of the interval between measurement times and the rotational speed of the azimuthal acoustic LWD apparatus, i.e., m1 and P<16, or m<1 and P.sub.0<16, the fixed time interval measurement mode may not achieve azimuth measurement.

(46) In view of the technical problem, embodiments of the present invention provide a measurement method for azimuth acoustic LWD. When an azimuthal acoustic LWD apparatus operates in a unipole mode or a dipole mode, the azimuthal acoustic LWD apparatus rotates with a drill tool, to cover all the sectors around a wellbore by adopting a fixed time interval measurement mode or an alternating time interval measurement mode according to a relationship of an interval between measurement times and a rotation speed of the azimuthal acoustic LWD apparatus, thereby achieving azimuthal acoustic LWD;

(47) in particular,

(48) when m1 and P16; or when m<1 and P.sub.0>16, if the fixed time interval measurement mode is adopted, the collected data can cover all the sectors around the wellbore;

(49) when m1 and P<16; or when m<1 and P.sub.0<16, if the fixed time interval measurement mode is adopted, the collected data cannot cover all the sectors around the wellbore, accordingly, if the alternating time interval measurement mode is adopted, the collected data can cover all the sectors around the wellbore;

(50) the alternating time interval measurement mode includes two measurement processes, as shown in FIG. 13 and FIG. 14, in particular,

(51) firstly, a first measurement is performed at a first interval t, the measurement times are T.sub.m; a second measurement is performed at a second interval t.sub.1, and the measurement times are also T.sub.m; and one azimuth measurement is completed within 2T.sub.m;

(52) wherein the second interval t.sub.1 is determined according to the first interval t; and the measurement times T.sub.m are determined according to the first interval t, the second interval t.sub.1, and the time t.sub.2 required for one measurement from the start of transmitting to the end of receiving;

(53) a method for determining the first interval t is as follows: the first interval t is selected according to impulse discharge characteristics of an acoustic transducer excitation circuit and an average power of the circuit, wherein t is greater than 0.1s;

(54) by taking n=16 as an example, a method for determining the second interval t.sub.1 according to the first interval t includes two cases:

(55) when m1, that is, PQ, and P<16,

(56) in a second measurement process, the number m.sub.1 of measurements when the azimuthal acoustic LWD apparatus completes one revolution is:

(57) $\begin{array}{cc}{m}_1=\frac{P_1}{Q_1}=\frac{60}{R{t}_1}& \left(3\right)\end{array}$

(58) wherein P.sub.1/Q.sub.1 is an irreducible fraction, P.sub.1 and Q.sub.1 are relatively prime, meaning that in the second measurement process, the azimuthal acoustic LWD apparatus completes Q.sub.1 revolutions, and a total of P.sub.1 measurements are completed;

(59) according to

(60) $m=\frac{P}{Q}=\frac{60}{Rt},$
it is derived that:

(61) 0$\begin{array}{cc}\frac{P_1}{Q_1}=\frac{t}{t_1}\frac{P}{Q}& \left(4\right)\end{array}$

(62) let P.sub.1/Q.sub.1>1, P.sub.1>16, the second measurement meets a requirement of covering all the sectors around the wellbore; and because values of the first interval t and the P/Q in the first measurement are known, the obtained second interval t.sub.1 meets the following condition:

(63) t1<tP/Q, and meets a requirement that P.sub.1 and Q.sub.1 are relatively prime, wherein P.sub.1>16;

(64) when m<1, that is, P<Q, and P.sub.0<16,

(65) when m<1, that is, when P<Q, e=1/m=Q/P=N+Q.sub.0/P.sub.0, a case where there is no measured data when the azimuthal acoustic LWD apparatus completes N revolutions is ignored, which may be transformed into the following form:

(66) $\begin{array}{cc}{m}_0=\frac{P_0}{Q_0},\mathrm{wherein}{Q}_0<P_0& \left(5\right)\end{array}$

(67) In the second measurement process, the number m.sub.1 of measurements when the azimuthal acoustic LWD apparatus completes one revolution is:

(68) $m_1=\frac{P_1}{Q_1}=\frac{60}{R{t}_1},$
wherein P.sub.1/Q.sub.1 represents an irreducible fraction, P.sub.1 and Q.sub.1 are relatively prime, meaning that in the second measurement process, the azimuthal acoustic LWD apparatus completes Q.sub.1 revolutions, and a total of P.sub.1 measurements are completed;

(69) according to

(70) $m_0=\frac{P_0}{Q_0}=\frac{60}{Rt},$
it is derived that:

(71) $\begin{array}{cc}\frac{P_1}{Q_1}=\frac{t}{t_1}\frac{P_0}{Q_0}& \left(6\right)\end{array}$

(72) let P.sub.1/Q.sub.1>1, P.sub.1>16; and because values of the first interval t and the P.sub.0/Q.sub.0 in the first measurement are known, the obtained second interval t.sub.1 meets the following condition:

(73) $t1<t\frac{P_0}{Q_0},$
and meets a requirement that P.sub.1 and Q.sub.1 are relatively prime, wherein P.sub.1>16.

(74) A method for determining time t.sub.2 required for one measurement from the start of transmitting to the end of receiving according to a measured source spacing and a range of wave velocities measured by of the azimuthal acoustic LWD apparatus is as follows:

(75) $\begin{array}{cc}{t}_2\frac{L_{\max }}{V_{\min }}& \left(7\right)\end{array}$

(76) wherein L.sub.max represents a distance between the transmitting transducers and the farthest receiving transducer array, and V.sub.min represents a minimal wave velocities which can be measured by the azimuthal acoustic LWD apparatus.

(77) A method for determining the measurement times T.sub.m according to the first interval t, the second interval t.sub.1 and the time t.sub.2 required for one measurement from the start of transmitting to the end of receiving is as follows:

(78) the total measurement time of each azimuth measurement is 2*T.sub.m, and operation times of the first and second intervals between measurement times are both T.sub.m, the time required for one measurement from the start of transmitting to the end of receiving is t.sub.2, and the total number of measurements within T.sub.m is

(79) $\frac{T_m}{t},$
and in order to ensure that 16 sectors have no vacant points throughout a sampling process, it must meet:

(80) $\begin{array}{cc}\frac{T_m}{t}\left(t_1-t\right)t-2t_2& \left(8\right)\end{array}$

(81) accordingly, T.sub.m must meet:

(82) $\begin{array}{cc}{T}_m\frac{\left(t-2t_2\right)t}{\left(t_1-t\right)}& \left(9\right)\end{array}$