The present application relates to the field of measuring formation resistivity from behind a casing, which can be referred to as Cased Hole Formation Resistivity or Resistivity Behind Casing. More specifically, in one embodiment, there are provided designs of electromagnetic (EM) cross casing resistivity tools and signal measurement that can provide measurements of formation resistivity from behind a casing.
After years of production, the owner of an oil and gas reservoir, usually an oil company needs to re-evaluate the reservoir for information, such as water saturation of the reservoir. The resistivity of the reservoir is a key parameter used to compute the saturation. In order to obtain resistivity, some cross casing resistivity tools have been developed by oil service companies. The operation principle of the tools is to measure an electric field with three electrodes that are completely attached to the casing, and the measurement can be converted to reservoir resistivity beyond the casing. The current operation principle has shortcomings, such as slow logging speed, requiring complete touch between measuring electrodes and casing, and the problems in the casing itself. Hence, there is a need for improved methods and systems for cross casing resistivity logging tools.
U.S. patent Ser. No. 11/249,216 B2 of Shanjun Li discloses a measurement method, which calculates the formation resistivity outside the casing by measuring the phase velocity, phase difference, amplitude attenuation, time difference while an alternating current flowing along the casing. However, this patent does not provide a method to measure the phase velocity, phase difference, amplitude attenuation, time difference when the alternating current flows outside the casing.
Therefore, there is a need to further design an instrument structure and a measurement method.
In the present invention, a new methodology is presented, which measures alternating current signals, including current, voltage, electric field, and magnetic field in frequency domain or time domain, to compute current speed, time difference, phase difference, and current amplitude decay instead of measuring voltage only. The speed, phase deference, and current amplitude decay have a relationship with formation resistivity outside of the casing, which can be used to compute the formation resistivity more efficiently.
The present invention provides a structure and a measuring method for cross-casing resistivity tool. Instead of measuring voltage used by the operation principle of the current method, in an embodiment, the present invention measures the current flow velocity, time difference, the current flowing between electrodes, phase difference, and current amplitude attenuation on the casing which are used to calculate the formation resistivity outside the casing.
One aspect of the present application is a device for measuring cross casing resistivity comprising at least one electrode transmitter, at least one electrode monitor, a current measuring circuit for measuring alternating current signal flowing through the electrode monitor along the casing, a power source, and a processor configured for calculating a parameter for current propagation along the casing based on the alternating current signal and for calculating resistivity of formation outside the casing based on at least one of the parameter for current propagation along the casing, and:
Another aspect of the present application is a method of measuring cross casing resistivity comprising:
One can obtain a better understanding of the present invention from the following detailed description of various embodiments. The attached drawings are only examples.
The drawings and following detail description are just examples to understand the present invention which is susceptible to various modifications and alternating forms. It should be understood, however, that the drawings and detailed description thereof are not intended to limit the scope of the appended claims.
As used herein, “alternating current” refers to an electric current that periodically reverses direction and changes its magnitude continuously with time or electric current pulse.
As used herein, “current measuring unit” refers to a device for measuring the alternating current signal on the wire in frequency domain or time domain.
As used herein, “cross casing resistivity” refers to measuring the resistivity of the formation outside the casing.
As used herein, “electrode” refers to a solid electrical conductor or a group of conductors through which current flows into or out of a power source or other medium. A set of electrical conductors consists of multiple electrical conductors with different azimuth angles.
As used herein, “electrode module” comprises electrodes and wires that are connected to the control circuit of the instrument and allow current to flow in or out of the electrode.
As used herein, “electrode transmitter” refers to electrode or electrode module used as a transmitter.
As used herein, “electrode monitor” refers to electrode or electrode module used as a monitor.
As used herein, “monitoring electrode module” comprises electrodes and wires that are connected to the control circuit of the instrument and allow current to flow from the electrodes.
As used herein, “transmitting electrode module” comprises electrodes and wires that are connected to the control circuit of the instrument and allow current to flow out of the electrode.
As used herein, “power” or “power system” refers to AC power.
As used herein, “alternating current signal” refers to current, voltage, electric field, and magnetic field.
V
0
=A
0
e
iθ
. (1)
Note:
V
1
=A
1
e
iθ
o (2)
The annular medium 702 can be made of any material, but magnetic medium is preferred.
V
2
=A
2
e
iθ
. (3)
The annular media 706 can be made of any material, but magnetic media is preferred.
Calculating the ratio of V1 and V2
the phase difference Phaseup and the amplitude attenuation Attup when the current passes through the monitoring electrode module R1107 and the monitoring electrode module R2108 are expressed as:
The phase velocity of current Iup′ 603 flowing from monitoring electrode module R1107 to monitoring electrode module R2108 is
where f is the frequency of the alternating current, and L is the spacing between R1107 and R2108.
The time difference while the alternating current passes through monitoring electrode modules or from the transmitting electrode module to an monitoring electrode module can be computed by analyzing the shape of the electric current pulse emitted by transmitting electrode module and measured by the current measuring circuits installed on the monitoring electrode modules and the transmitting electrode module, and the group velocity can be computed with the time difference and the spacing between the monitoring electrode modules or between the transmitting electrode module and the monitoring electrode module.
Note:
Note: The parameters used in the calculation of
Note: The parameters used in the calculation of
Based on the fact that there is a one-to-one correspondence relationship between the phase velocity of the alternating current flowing through the monitoring electrode modules, the time difference while the alternating current flows through the monitoring electrode modules has a one-to-one correspondence relationship with the formation resistivity outside of the casing. The formation resistivity outside the casing can be calculated using the time difference while the alternating current flows through the monitoring electrode modules. And the formation resistivity outside the casing can be calculated using the time difference while the alternating current flows from the transmitting electrode module to the monitoring electrode module.
V′
1
=A′
1eiθ′
The voltage measured by the monitoring electrode module R2′ 1202 is
V′
2
=A′
2
e
iθ′
. (9)
Calculate the ratio of V′1 and V′2
The phase difference Phaseddn and the amplitude attenuation Attdn when the alternating current passes through the monitoring electrode module R1′ 1201 and the monitoring electrode module R2′ 1202 are expressed as:
The phase velocity of current Idn 303 flowing from monitoring electrode module R1′ 1201 to monitoring electrode module R2′ 1202 is
The current phase difference, amplitude attenuation and phase velocity measured by the device structure shown in
The equation (2) to equation (16) only can be used to compute formation resistivity outside casing while the alternating current flows between two monitoring electrode modules. However, the ratios between V0 measured by the current measuring circuit installed in the transmitting electrode module and V1, V2, V′1 and V′2 can also be used to compute phase difference, amplitude attenuation, phase velocity while the alternating current flows between the transmitting electrode module and monitoring electrode modules For example: using the formula
the phase difference, Phase1, and the current amplitude attenuation, Att1, produced by the current flowing from the transmitting electrode module T 109 to the monitoring electrode module R1107 can be calculated.
By the following formula,
the phase velocity of the alternating current flowing from transmitting electrode module T 109 to monitoring electrode module R1107 can be calculated.
The phase difference, amplitude attenuation and phase velocity calculated from the transmitting electrode module to each monitoring electrode module can be used to calculate the formation resistivity outside the casing, and the time difference while the current flows from the transmitting electrode module to the monitoring electrode module can be used to calculate the formation resistivity outside the casing.
In one embodiment, the present invention provides a method for measuring alternating current outside the casing. The monitoring electrode module is connected to the return electrode of the control system through a wire, and the current flows to the return electrode. A current measuring circuit is installed on the monitoring electrode module and measure alternating current signal passing the monitoring electrode module, and the measured alternating current signal by the current measuring circuit reflects the current parameter when the alternating current outside the casing passes through the monitoring electrode module.
In one embodiment, the present invention provides a method for measuring the alternating current outside the casing, the monitoring electrode module is connected to the metal casing through a wire, and part of the current passes through the monitoring electrode module in which a current measuring circuit is installed, the wire, the casing, the formation, and flows to the return electrode. The measured alternating current signal by the current measuring circuit reflects the current parameter when the alternating current outside the casing passes through the monitoring electrode module.
In one embodiment, the present invention provides a method for measuring the alternating current outside the casing, the monitoring electrode module is connected to the electrode on ground through a wire, part of the current passing through the monitoring electrode modules, wires, electrodes and the electrode on ground flows back to return electrodes. Current measuring circuits are installed on the monitoring electrode modules and measure alternating current signal of the alternating current passing the monitoring electrode modules. The measured alternating current signal by the current measuring circuit reflects the current parameters when the alternating current flows outside the casing through the monitoring electrode module.
In one embodiment, the present invention provides a method of measuring alternating current when the alternating current flows out of the transmitting electrode module, the current measuring circuit is installed on the transmitting electrode module and measure the alternating current signal of the alternating current flowing out the transmitting electrode module, and the measured alternating current signal reflects the current parameter when the alternating current flows out the transmitting electrode module.
In one embodiment, the present invention provides a method for measuring the phase difference when the alternating current outside the casing flows through the monitoring electrode
modules. The ratio, can be used to compute the phase difference and current amplitude decay while the alternating current flows between monitoring electrode modules R1 and R2, where V1 is the measurement of the monitoring electrode module R1, and V2 is the measurement of the monitoring electrode module R2.
In one embodiment, the present invention provides a method for measuring the phase velocity of the alternating current outside the casing flowing between the monitoring electrode modules.
can be used to compute the phase difference, Phase, and to compute phase velocity
while the alternating current flows between monitoring electrode modules, where V1 is the measurement of the monitoring electrode module R1, and V2 is the measurement of the monitoring electrode module R2.
In one embodiment, the present invention provides a method for measuring the alternating current decay while the alternating current flows between monitoring electrode modules. Using
the current amplitude attenuation can be expressed as Att=−20 log (|Ratio|). where V1 is the measurement of the monitoring electrode module R1, and V2 is the measurement of the monitoring electrode module R2.
In one embodiment, the present invention provides a method for measuring the phase difference between the transmitting electrode module and the monitoring electrode module, while the alternating current flows from the transmitting electrode module to the monitoring electrode module. Formula
is used to compute the phase difference, where VT is the measurement of the current measuring circuit on transmitting electrode module, VR is the measurement of the current measuring circuit on monitoring electrode module R.
In one embodiment, the present invention provides a method for measuring the phase velocity while the alternating current flows from the transmitting electrode module to an monitoring electrode module.
is used to compute the phase difference, phase, and
is used to calculate the phase velocity, where VT is the measurement of the current measuring circuit on transmitting electrode module, VR is the measurement of the current measuring circuit on monitoring electrode module R, f is the frequency, and L is the spacing between the transmitting electrode module and the monitoring electrode module.
In one embodiment, the invention provides a cross casing resistivity device, using the alternating current phase difference between monitoring electrode modules to calculate the formation resistivity outer casing.
In one embodiment, the invention provides a cross casing resistivity device, using the alternating current attenuation between monitoring electrode modules to calculate the formation resistivity outer casing.
In one embodiment, the invention provides a cross casing resistivity device, using the alternating current phase velocity between monitoring electrode modules to calculate the formation resistivity outer casing.
In one embodiment, the invention provides a cross casing resistivity device, using the time difference while alternating current flows between monitoring electrode modules to calculate the formation resistivity outer casing.
In one embodiment, the invention provides a cross casing resistivity device, using the alternating current phase difference between transmitting electrode module and monitoring electrode module to calculate the formation resistivity outer casing.
In one embodiment, the invention provides a cross casing resistivity device, using the alternating current attenuation between transmitting electrode module and monitoring electrode module to calculate the formation resistivity outer casing.
In one embodiment, the invention provides a cross casing resistivity device, using the alternating current phase velocity between transmitting electrode module and monitoring electrode module to calculate the formation resistivity outer casing.
In one embodiment, the invention provides a cross casing resistivity device, using the time difference while alternating current flows between transmitting electrode module and monitoring electrode module to calculate the formation resistivity outer casing.
In one embodiment, the invention provides a cross casing resistivity measurement system, and transmitting electrode module contacts with casing, and in another embodiment, transmitting electrode module does not contact with casing.
In one embodiment, the present invention provides a cross casing resistivity measurement system that the monitoring electrode module contact the casing, and in another embodiment, the monitoring electrode module does not contact with casing.