Patent Application
20190360329
The present invention relates to the field of mineral resources exploration and development technology, especially to the field of mine geophysical (logging) technology, drilling measurement technology and measurement while drilling technology, and more particularly to a through bit dipole acoustic logging transmitter and logging device.
The evaluation of the formation before and after hydraulic fracturing for the larger horizontal well (e.g. more than 1000 m) is the hotspot, difficulty and key technology of the shale gas development in China. The through bit cross-dipole acoustic logging technology is the preferred method of measurement to solve such problem by far.
The through bit logging is a new technology developed in recent years. The through bit logging refers to a way in which the logging instrument passes through the drill bit of special mechanical design and enters the measurement section for logging data acquisition. The through bit logging technology has its unique advantages, mainly including the following: {circle around (1)} Reducing engineering risks from drilling operations, because in most of the operation time the logging instruments are placed in the drill pipe so as to be protected; {circle around (2)} Saving operating time significantly. The through bit logging is able to carry out logging operations without the need for taking the drilling tool out of the ground, which saves the well-completion practice time greatly compared with the wireline logging, which should be performed after taking the drilling tool out. {circle around (3)} Obtaining continuous and reliable logging data. The through bit logging is the way that the logging instruments assembly passes through the drill pipe to measure the target formation when the drill bit and the drill pipe stop vibrating. Therefore, the quality of the data obtained is stable and reliable. {circle around (4)} Performing survey logging. The through bit logging is able to enter the open hole section to measure without taking the drill out and obtain a variety of important information of the reservoir for guiding the continued drilling, and providing physical basis for scientific drilling.
The through bit logging requires the logging instrument with small outside diameter, which is 54 mm at present, mainly including natural gamma, well temperature, induction resistivity, natural potential, formation density, well diameter, neutron porosity and monopole interval transit time logging. The through bit logging technology is suitable for harsh well conditions, such as horizontal well, high angle deviated well, wellbore collapse and shale expansion. Measurement in the North Sea exploratory well and evaluation well, has overcome the problems that the conventional wireline logging encountered, and obtained high-quality logging data.
The through bit monopole interval transit time instrument is used mainly for the shear wave and longitudinal wave velocity measurement. The rock properties, including Poisson's ratio, static Young's modulus and minimum horizontal stress gradient, can be calculated with the longitudinal wave velocity and shear wave velocity recorded by array receivers on the monopole acoustic logging instrument, combined with the density logging information. The stress data calculated above and the quality parameters being able to reflect the reservoir quality (e.g. clay content and porosity) are useful for selecting the best hydraulic fracturing effect formation. However, the monopole acoustic logging instrument cannot measure the shear wave velocity of the formation in the soft and ultra-soft formation, and therefore cannot get the properties of the rock, which is mainly caused by the symmetric monopole acoustic source. The main solution to such problem is to use a dipole transducer and a cross-dipole transducer as a transmit transducer to measure the shear wave velocity of the formation. However, there have been few public reports on the commercial use of through bit cross-dipole acoustic logging instrument.
At present, the outer diameter of the conventional dipole acoustic wireline logging instrument is 90 mm, and there are two main kinds of transducers (also known as transmitters), one of which is an electromagnetic type dipole acoustic transducer, and the other is a piezoelectric transducer type usually working in bending vibration mode with laminated-type. In general, the laminated-type bending vibration piezoelectric transducer is made of piezoelectric ceramic plates polarized in the thickness direction and a metal aluminum substrate by means of bonding. As the outer diameter of the through bit instrument is very small (54 mm), the geometrical dimensions of the piezoelectric crystals and the substrate of the bending vibrator with laminated structure are correspondingly reduced such that the radiating surface of the bending vibrator is narrowed after the assembly of the cross-dipole transducer compared with the conventional cross-dipole acoustic logging instrument, resulting in the weakening of the excitation energy of the transducer and the lowering of the signal-to-noise ratio.
The purpose of the invention is to provide a transmitter of a through bit dipole acoustic logging device and the logging device comprising the same against the shortcomings of the prior art, mainly the structure design of the acoustic transmitter and its logging device, which can meet the acoustic performance requirements of the small diameter cross-dipole acoustic logging transmitter under the conditions of satisfying the mechanical requirements of the through bit logging instrument.
To solve the above problems, in the first aspect, the invention provides a transmitter of a through bit dipole acoustic logging device, and the transmitter includes a substrate and at least 2 piezoelectric ceramic plates respectively on either side of the substrate; wherein the piezoelectric ceramic plate is composed of at least one block of piezoelectric ceramic units; wherein the lengthwise direction of the piezoelectric ceramic units is along the width direction of the piezoelectric ceramic plate, the width direction of the piezoelectric ceramic units is along the thickness direction of the piezoelectric ceramic plate, and the thickness direction of the piezoelectric ceramic units is along the lengthwise direction of the piezoelectric ceramic plate; the polarization directions of the piezoelectric ceramic units are along the thickness direction of the piezoelectric ceramic plates; when electric excitation is applied along the length of the piezoelectric ceramic plate, the piezoelectric ceramic plate on one side of the substrate is extended while the piezoelectric ceramic plate of the other side shortened, pushing the substrate to form a bending vibration, transmitting the thrust to the media and generating acoustic waves.
Preferably, each of the piezoelectric ceramic plates is composed of 2n blocks of piezoelectric ceramic units, every two adjacent piezoelectric ceramic units of the 2n blocks of piezoelectric ceramic units belonging to the same plate are polarized in opposite direction, the 2n blocks of piezoelectric ceramic units belonging to the same plate are connected in parallel; wherein n is a natural number.
Preferably, the substrate is provided with through-holes at both ends along the length direction, and is fixed via fixed part through the through-hole to the though bit dipole acoustic logging device.
It is further preferred that the piezoelectric ceramic plate is formed by bonding the2n blocks of piezoelectric ceramic units with an adhesive.
It is further preferred that the adhesive is an epoxy resin.
Preferably, the piezoelectric ceramic plates and the substrate are bonded with an adhesive.
It is further preferred that the adhesive is an epoxy resin.
Preferably, the substrate can be titanium, copper, aluminum, low expansion alloy, or composite materials.
Preferably, the material of the piezoelectric ceramic plate is PZT4, PZT5 or PZT8.
Preferably, the electrodes in the same position on both sides of the substrate are connected in the identical way, but the polarization of the piezoelectric ceramic units in the same position on both sides is the opposite.
Preferably, the electrodes in the same position on both sides of the substrate are connected in the opposite way, but the piezoelectric ceramic units in the same position on both sides are polarized in the identical way.
In the second aspect, the invention also provides a through bit dipole acoustic logging device including the transmitter of the first aspect.
Compared with the conventional laminated-type dipole transmitters, the design of the segmented dipole transmitter of the invention can increase the bending deformation of the transmitter, increase the outward thrust from the transmitter surface, and thereby increase the transmitting energy of the transmitter; the invention can realize the transmission of the lower frequency acoustic wave in the limited space, and is more suitable for the shear wave measurement in the soft formation and even the ultra-soft formation.
Hereinafter, an embodiment of the invention will be described in detail with reference to the accompanying drawings, in which:
The present invention will be further described hereinafter with drawings and specific embodiments, but it should be understood that these embodiments are for illustrative purposes only, and should not be construed as limiting the invention in any form, that is, it is not intended to limit the protection scope of the invention.
In an embodiment of the present invention, a transmitter of a through bit dipole acoustic logging device and a related through bit dipole acoustic logging device are provided. The transmitter includes a substrate, at both sides of which at least 2 piezoelectric ceramic plates are symmetrically disposed; wherein each of the piezoelectric ceramic plates is composed of at least one piezoelectric ceramic units. The lengthwise direction of the piezoelectric ceramic elements is along the width direction of the piezoelectric ceramic plates, the width direction of the piezoelectric ceramic units is along the thickness direction of the piezoelectric ceramic plates, and the thickness direction of the piezoelectric ceramic units is along the lengthwise direction of the piezoelectric ceramic plates. The polarization direction is along the thickness direction of the piezoelectric ceramic units. During operations, the piezoelectric ceramic plate on one side of the substrate is extended while the piezoelectric ceramic plate of the other side shortened, pushing the substrate to form a bending vibration, transmitting the thrust to the media and generating acoustic waves. The piezoelectric ceramic units may be the same, and may be of different sizes and shapes.
The piezoelectric ceramic plate may be composed of 2n piezoelectric ceramic units, wherein n is natural number. In an example, adjacent units of the 2n piezoelectric ceramic units on the same side of substrate are polarized in an opposite way while their respective electrodes are connected in parallel; in this way, the electric capacity and charge amount of each of the piezoelectric ceramic plates are equivalent to 2n times the electric capacity of each piezoelectric ceramic unit, thereby the overall performance of the transducer according to the embodiment of the present invention can be improved. Of course, other methods can be taken, for example, 2n adjacent piezoelectric ceramic cells in the same side of the piezoelectric ceramic plate may have the same polarization direction, while the respective electrodes are connected in series.
As shown in
Through holes 321 may be provided at both ends of the substrate, and the substrate 32 is fixed to the through bit dipole acoustic logging device 1 with fixing parts passing through the through holes 321.
In particular, for each piece of piezoelectric ceramic plate, it may be made of 2n piezoelectric ceramic rectangular columns which are spliced and adhered together, and each piezoelectric ceramic rectangular column is called a piezoelectric ceramic unit. The lengthwise direction of the piezoelectric ceramic elements is along the width direction of the piezoelectric ceramic plates, the width direction of the piezoelectric ceramic units is along the thickness direction of the piezoelectric ceramic plates, and the thickness direction of the piezoelectric ceramic units is along the lengthwise direction of the piezoelectric ceramic plates.
Therefore, each piece of piezoelectric ceramic plate is equivalent to a piezoelectric ceramic stack composed of a plurality of piezoelectric ceramic units; the polarization direction is along the thickness direction of the piezoelectric ceramic units (the lengthwise direction of the piezoelectric ceramic plate), and the polarization directions of every two adjacent piezoelectric ceramic units are opposite, and the electrode connection mode of the 2n piezoelectric ceramic units is a parallel connection. When an external electric signal is applied, the adjacent piezoelectric ceramic units may be simultaneously elongated (or shortened) in the thickness direction (the piezoelectric ceramic plate is elongated (or shortened) in the lengthwise direction); if a stress is pre-applied along the length of the piezoelectric ceramic plate, the piezoelectric ceramic plate will be elongated (or shortened) in the direction of length.
During operations, the piezoelectric ceramic plates on both sides of the substrate are electrically stimulated along the length of the piezoelectric ceramic plates. At a time, the piezoelectric ceramic plate 31 on one side of the substrate 32 is extended while the piezoelectric ceramic plate 31 of the other side shortened, pushing the substrate 32 to form a bending vibration, transmitting the thrust to the media and generating acoustic waves. One explanation is that the acoustic wave vibrates along radial direction of the borehole, propagates along the axial direction of the borehole, and generates a bending vibration down the borehole, from which the dipole wave velocity could be obtained approximately in the formation.
In order to realize the elongating or shortening at different directions of piezoelectric ceramic plate 31 at different sides, it is necessary to reasonably distribute the polarization directions of the piezoelectric ceramic units and the connection modes of the electrodes.
Certainly, those skilled in the art may realize that other connection patterns beyond that in
It is to be noted that 2n piezoelectric ceramic plates 31 may be uniformly distributed on both sides of the substrate 32, as shown in
In one example, the substrate 32 is generally a metal material such as titanium, copper, aluminum, low expansion alloy, or composite materials.
In another example, the piezoelectric ceramic plate 31 is made of the piezoelectric ceramic units 311 by means of bonding with an adhesive. The adhesive is preferably a polymer material such as an epoxy resin, but it is not limited to such an adhesive. Preferably, the piezoelectric ceramic plate 31 and the substrate 32 are bonded with an adhesive. It is further preferred that the adhesive is a polymer material such as an epoxy resin, but it is not limited to such an adhesive.
In yet another example, the piezoelectric ceramic plate material is PZT4, PZT5 or PZT8, but it is not limited to these types of piezoelectric ceramic materials.
Since the piezoelectric ceramic plate 31 adopts multi-segmented piezoelectric ceramic elements, the dipole emitter in the embodiment of the invention may be referred as a segmented dipole emitter. The outward thrust generated by the segmented dipole transmitter is not only related to the size parameters of the transmitter, but also to the parameters of the piezoelectric ceramic material, especially to d33 piezoelectric constant.
Conventional laminated type dipole transmitters is also composed of a substrate and piezoelectric ceramic plates on both sides of the substrate. When applying electric excitation to the piezoelectric ceramic plates, the piezoelectric ceramic plate at one side elongates in the length direction while the piezoelectric ceramic plate at the other side shortens in the length direction, therefore the emitter develops an overall bending vibration.
Conventional laminated type dipole transmitters differs from the segmented dipole transmitters according to the embodiments of the present invention in that, in the conventional type laminated dipole transmitters, piezoelectric ceramic plate is a solid block of piezoelectric material, the polarization direction being along the thickness direction of the piezoelectric ceramic plate. With respect to conventional laminated dipole emitter, the outward thrust generated by bending vibration is not only related to the size parameters of the transmitter, but also related to parameters of piezoelectric ceramic materials, especially the d31 piezoelectric constant.
The type of piezoelectric ceramic material used in the transmitter is an emissive PZT4 of which the value of a d33 piezoelectric constant is more than twice the d31 piezoelectric constant. For transmitters of the same geometric dimensioning, the segmented transmitter should be superior to the conventional type in performance. In through bit acoustic logging, a small-diameter instrument requires a narrowing of the radiation surface of the transmitter; however, in the case where the radiation surface is narrowed, the radiation energy of the conventional transmitter will decrease, however the segmented transmitter can meet the logging requirements.
In order to highlight the application advantages of the segmented dipole transmitter of the invention in the logging, the admittance properties of the conventional and the segmented dipole transmitters are measured in the free state of air, and in the figures, the thick line represents the conventional dipole transmitter, and the thin line represents the segmented dipole transmitter.
As can be seen from the comparison of the measurement results in
The cross-dipole acoustic data can be used to determine the shear wave circumferential anisotropy features, and further obtain the anisotropy information of the formation around the borehole wall, and it has a wide range of applications especially in the study of stratigraphic fracture features and the geostress measurement.
Although the invention has been described to some extent, it will be apparent that various appropriate changes for each condition may be made without departing from the spirit and scope of the invention. It is to be understood that the invention is not limited to the described embodiments, and is within the scope of the claims, including the equivalent of each factor described above.
In the specific embodiments described above, the purpose, technical scheme and advantageous effects of the invention are described in further detail, and it is to be understood that the above description is merely a specific embodiment of the invention, and is not intended to limit the scope of protection of the invention, and any modifications, equivalents, improvements and the like within the spirit and principles of the invention should be contained in the protection scope of the invention.
| Number | Date | Country | Kind |
|---|---|---|---|
| 201710214045.2 | Apr 2017 | CN | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/CN2018/071365 | 1/4/2018 | WO | 00 |
