KR100270299B1 - Elastic wave detector and method for measuring shear wave - Google Patents

Abstract

The elastic modulus and shear modulus obtained from the seismic wave together with the P-wave together with the shear wave (S-wave) are used to increase the reliability of the grouting performance. The present invention relates to a seismic wave measuring device capable of measuring a wave and a shear wave measuring method using the same, wherein at least one pair of detection holes having the same size are drilled at a position opposite to each other, so that one side of the detection hole has a ceramic piezoelectric element (24) type oscillator (22). ) Is provided with a built-in acoustic wave oscillator (A) and a detector (B) containing a ceramic piezoelectric element (32a, b) type acoustic wave oscillator 30 is installed in the opposite side detection hole, the oscillator (A) and the detector ( With the cable of B) connected to the ground control device (C), the trigger signal generated by applying high voltage to the oscillator (A) is received by the detector (B) to record the P-wave and S-wave, and the S-wave and Room of detector (B) A station is a measurement method of synthesizing reads the S- wave measured by adjusting the.

Description

Seismic measuring instrument and shear wave measuring method using the same

The present invention improves the reliability of the grouting performance by using the elastic modulus and shear modulus together with the P-wave and the shear modulus and shear modulus. The present invention relates to a seismic wave measuring device capable of measuring waves and S-waves and a shear wave measuring method using the same.

Due to the topographical characteristics and the structural characteristics of the economy and industry centered on large cities, the development of underground spaces such as tunnels for building subways and high-speed transportation networks, underground logistics storage facilities, and underground cities with complex functions such as economy, culture and welfare have been rapidly increasing. It is showing. In order to meet such construction environment, the design and construction of safe and high quality underground structures requires the measurement of precise ground property, quality control and safety diagnosis.

A seismic measurement method is one of the detection methods applied to earthwork quality evaluation. The seismic measurement is used for the calculation of the properties of the ground needed to analyze the mutual behavior of the ground and structures under dynamic loads such as earthquakes and vibrations. It is widely applied to earthwork quality management such as quality and soundness evaluation of cast pile, tunnel lining, and rock grouting.

The seismic measurement method mainly used in civil engineering is cross hole measurement method using borehole, down hole measurement method, surface wave measurement method using surface wave, SASW tests using surface wave, and it is refracted to the ground boundary surface In addition to the refraction measurement method for measuring the leading wave arriving, a technique for image processing a two-dimensional stiffness distribution using an elastic tomography method has been introduced. Tomography technology has been developed mainly for geophysics and exploration purposes and has recently been applied to civil engineering.

Tomography uses a phenomenon in which the amount of energy attenuation of the penetrating X-rays varies depending on the density of cells passing through the X-rays in a CT (computed tomography) scanner. It is tomography that imaged the distribution of density obtained from the numerical value of attenuation of X-ray energy projected from various angles around the brain. Seismic tomography is the same principle, and it is to reconstruct the rigid component gun of the ground image by measuring the transit time of the seismic wave related to the stiffness of the ground.

CT scanners can transmit X-rays in 360 ° around the brain to obtain accurate tomographic images of the diagnosis site.However, seismic tomography for ground surveys places oscillators and detectors in two detection holes, limiting the path through which the seismic waves are transmitted. Therefore, it is a priority to resolve the lack of data necessary for reconstitution of the water component gun.

CT scanners can transmit X-rays in 360 ° around the brain to obtain accurate tomographic images of the diagnosis site.However, seismic tomography for ground surveys places oscillators and detectors in two detection holes, limiting the path through which the seismic waves are transmitted. The lack of data necessary for the reconstruction of water constituents is a prerequisite.

In Figure 1, the method for performing the tomography of the ground using the acoustic wave is first drilling two detection holes (H ₁ , H ₂ ) and the oscillator (a) is installed in the detection hole (H ₁ ) to oscillate the acoustic waves in multiple angles In the opposite detection hole (H ₂ ), a detector (b) is installed to measure the wavelength reached and to measure the passage time of the acoustic wave on each propagation path, and to reconstruct the stiffness distribution of the ground using the passage time as data.

In Fig. 2, (a) corresponds to data collection of a CT scanner, and (b) is an array of oscillator-detectors that collects data using two detection holes in the ground survey. Unlike (a), (a), since the seismic waves are transmitted only between two detection holes, the data collection necessary to reconstruct the cross-sectional image is insufficient. This is a fundamental limitation of tomography for soil investigation.

Other conventional seismic measuring equipment is using a primer, a compressed air gun or an electrical sparker as the oscillator, and a hydrophone as the oscillator, and the water filled in the borehole as the elastic wave transmission medium of the ground and measurement period. It is impossible to adjust, so only P-wave can be measured. S-wave cannot be measured, so the measurement reliability is low, heavy and complicated operation, which makes measuring work difficult, and it is impossible to measure in horizontal and inclined detectors. Big too.

In order to improve the shortcomings of the seismic measuring instrument, the S-wave can be measured together with the P-wave, and precise measurement is possible not only in the horizontal detection hole but also in the inclined detection hole, and the repeatability, handling and maintenance of the elastic wave oscillation in the oscillator It is desired to have water retention.

According to the present invention, the oscillation oscillator oscillator and the detector oscillator have a ceramic piezoelectric element and an acoustic wave meter mainly composed of + and-electrodes, and at least one pair of detection holes are drilled at opposing positions. The oscillator is installed and the detector is installed at the opposite side of the detector. The acoustic wave of the oscillator is collected by the detector to measure the P-wave, and then the direction of the detector is changed at the same position to measure the opposite S-wave. By combining two S-waves and clearly identifying the arrival times of P-waves and S-waves, especially S-waves, we provide a measurement method using seismic waves to obtain more accurate information on the performance of grouting.

1 is a conceptual diagram of seismic tomography

2 is a layout view of an oscillator and a detector for measuring acoustic waves

3 is a partial cutaway side view of the oscillator;

4 is an exploded view of the oscillator

Figure 5 (a) is the oscillator, (b) is a front view of the oscillator

6 is a perspective view of a ceramic piezoelectric element and an electrode plate;

7 is a cross-sectional view of a model for measuring acoustic waves

8 is a cross-sectional photograph of the model reconstructed by the measurement of the cross-hole type

9 is a cross-sectional photograph of a model in the case of imaging by various algorithms

10 is a cross-sectional photograph of a model reconstructed by the measurement of the front shape

11 is an explanatory diagram of visibility phenomenon of electron microscope according to measurement angle

12 and below relate to a detection example,

12 is an elucidation of the detection hole

Fig. 13 is a radial diagram of the far region P-wave and S-wave due to the point load

14 is a schematic plan view of the oscillator and the sensor in close contact with the detection wall;

15 is a waveform diagram of a P-wave

16 is a waveform diagram of an S-wave and a synthesized S-wave;

17 is the velocity and Poisson's ratio of the seismic wave by the depth of the detection hole

18 is a speed comparison diagram of a compressed wave

<Description of the code | symbol about the principal part of drawing>

A: oscillator B: detector

2: board 3: hook

4: air supply pipe 5a, b: cable

6: circuit board case 7: bottom cover

8a, b: cable tube 9: band support

10: suspension span 11: air bag

12: band 20: oscillator

21 housing 21a cylinder

21d: RAM 22: Oscillator

24, 32a, b: piezoelectric element 23a, 33a: negative electrode plate

23b, 33b: bipolar plate 25: compression spring

26: band cup

In Fig. 3, the oscillator A for the acoustic wave measuring instrument attaches the hook 3 to the center of the upper surface of the string plate 2 so that it can be lowered and raised on the tip of the direction bar, and the compressor is compressed on the edge of the string plate 2. The air supply pipe (4) arranged to pass air through the airbag and the external power supply are secured to prevent flow through the internal electric circuit and the cables (5a, b) for conducting current to the oscillator.

Hanging and fixing the circuit board case 6 in which the electronic board is built in the bottom of the string board 2, and downing a pair of cable pipes (8a, b) in the center of the bottom of the circuit board case 6, One side of the bottom of the (7) embraces the cable pipe (8a, b) about half, and down the band support (9) surrounding the band for fixing the upper end of the air bag, and on the opposite side down the suspension for the oscillator (10). Here, the cable tubes 8a and b are oscillating cable protective tubes which are drawn out below the circuit board cylinder 6 and connected to the oscillator side. The band support 9 forms a catching jaw 9a at the bottom of the outer surface to prevent the band around it from sliding down.

Because P-waves are the fastest, they can be measured to some degree without the oscillator and detector orientation. In other words, the arrival time of the P-wave can be measured by taking the initial motion of the acoustic wave in the acoustic wave recording. However, since the S-wave is slower than the P-wave, it is very difficult to accurately identify the arrival point of the S-wave when the excitation of the P-wave overlaps with the S-wave. In order to overcome these reading difficulties and obtain seismic information that can accurately identify the S-wave arrival point, the oscillator and the detector must be oriented at the same time so that they can be securely attached to the air gap of the detection hole.

Air bag (11) is a dash bore contact means of the instrument to close the gap when there is a gap between the outer peripheral surface of the oscillator (A) and the circumferential wall of the borehole, it is made of fabric excellent in tensile strength and tear strength Tube (same material and weave as fire hose). The fire hose is wrapped in a woven fabric, which is resistant to abrasion, less puncture, less expensive, and easy to maintain. The air bag 11 has a length that is slightly loosened to the band cup 26 by turning the oscillator 20 behind the suspension stem 9 at the same position as the band support 8. The upper end in close contact with the rear surface of 9) is fixed to the band support 9 side and the lower end in close contact with the rear surface of the band cup 26 with the band 12, respectively. And the end of the air supply pipe (4) is connected to the air bag (11) pneumatically. The air bag 11 also serves as a vibration shield in protecting the transmitter A, especially the oscillator 20 from its impact when oscillating.

Looking at the oscillator 20 with Figure 4, it comprises a housing 21 and the oscillator 22. The frequency component of the acoustic wave energy generated in the oscillator 22 is greatly influenced by the weight of the housing 21. The housing 21 is made of stainless steel to operate in the frequency range of about 10kHz in order to be able to use freely in rock and concrete. The housing 21 has one or more oscillators 22 accommodating cylinders 21a of the same size up and down. The upper surface of the housing 21 has a flange (21b) to be attached to the lower end side of the suspension span 10, the flange 21b is bored by a lateral fastening bolt hole (21c) to enable bolting do.

In the center of the bottom of the housing 21, a ram 21d is attached or formed integrally, and the ram 21d is loosely covered with a band cup 26 loaded with a compression spring 25. The compression spring 25 pushes out the band cup 26 when the air is blown out of the air bag 11 so that the air bag 11 is not stretched. When the compressed air enters the air bag 11, the compression spring 25 becomes tight. 26) is contracted by the accompanying force. The band cup 26 follows the air bag 11 when it is stretched and supports the air bag 11 so as not to be tattered, and at the same time, when the oscillator A is installed in the detection hole, the band cup 26 falls to its bottom. Even if an accident occurs, the compression spring 25 also functions as a shock absorber, and the upper half is made larger than the diameter of the lower half so that the upper band 12 does not slide upward. Reference numeral 27 denotes a striking plate that is attached to the substrate 22d of the oscillator 22 and transmits the vibration generated in the oscillator 22 to the detection wall while maintaining the gap between the oscillators.

In Fig. 5A, the base of the oscillator 22 is a plurality of negative and positive electrode plates 23a and b and a piezoelectric element 24 made of ceramic. That is, the thin ceramic piezoelectric element 24 and the negative electrode plate 23a, the piezoelectric element 24 and the positive electrode plate 23b as described above are arranged in a plurality of stages on the rear surface of the substrate 22a, and the negative electrode plate 23a and the positive plate (23b) surrounds the insulating paper 28 on the main surface after connecting the copper poles and selectively connects the cathode wire and the anode wire drawn out of the insulating paper 28 to the cables 5a and 5b. The piezoelectric element 24 has a thickness of 1.25 mm, and when 20 sheets are stacked, a maximum electric field of 20,000 V / in can be generated at a voltage of 1 kV.

The elastic modulus of the piezoelectric element 24 is about the middle of the elastic modulus of aluminum and iron. The impact stress is very large but the deformation is very small. By operating the piezoelectric element 24 at the resonance frequency, the amplitude of deformation can be greatly increased. The resonance frequency of the oscillator 22 which can fit into the typical detection hole size NX is 49-58 KHz. In order to obtain a good quality image as an important doubling phenomenon to be considered in the selection of the frequency component, it is preferable to measure using an acoustic wave having a high frequency component. On the other hand, high frequency has a severe attenuation, which limits the transmission distance of the acoustic wave energy. In consideration of this point, the weight of the piezoelectric element 24 is reduced to reduce the resonance frequency and increase the inertia, thereby obtaining an effect of generating a large elastic stress. The concept of placing a weight on the piezoelectric element 22a is a technique widely applied in the design field of a large acceleration sensor. However, in the present invention, there is a fundamental difference in that the resonance is suppressed in order to obtain a horizontal response curve in the general acceleration sensor while using the resonance phenomenon.

In FIG. 5 (b), the sensor B for the seismic measuring instrument differs only in the form of the oscillator 30 and the electronic circuit housed in the electronic circuit board chamber, and the rest is the same as the oscillator A described above. That is, the detector 30 for the detector B includes the thin piezoelectric element 32a and the negative electrode plate 33a of the substrate 31, the thick piezoelectric element 32b, the positive electrode plate 33b, the thin piezoelectric element 32a, and the positive electrode plate ( 33b), the thick piezoelectric element 32b, the negative electrode plate 33a, and the thin piezoelectric element 32a are stacked in this order, and the negative electrode plate 33a and the positive electrode plate 33b are connected to each other with the same polarity, and then the insulating paper 34 is wrapped around the main surface. The cathode wire and the anode wire drawn out of the insulating paper 34 are connected to the cable. The reason why the intermediate piezoelectric element 32b is a thick ceramic is to maximize signal-to-noise ratio in order to output a high electrical signal even with small mechanical deformation, that is, vibration.

When voltage is applied to the piezoelectric elements 24 (32a and b), electric field changes and electric charges are generated. In other words, the conversion between mechanical energy and electrical energy becomes possible. The piezoelectric elements 24 (32a, b) are manufactured to have piezoelectric properties by polarization treatment with lead titanium zirconate. These piezoelectric elements 24 and 32a and b have a disk type having a large value in use in the thickness expansion mode.

When voltage is applied to the negative electrode plates 23a and 33a and the positive electrode plates 23b and 33b, the piezoelectric elements 24 and 32a and b are deformed like springs to charge electrical energy like a capacitor. Once a sufficient amount of electrical energy is charged, the negative electrode plates 23a and 33a and the positive electrode plates 23b and 33b are short-circuited to emit an impact energy while instantaneously forming an electric field. At the same time, elastic energy is generated as springs that have been retracted elastically spring. This elastic energy is proportional to the maximum amount of electric energy charged in the piezoelectric elements 24 (32a, b). At the same time, the electric energy charged in the capacitor is proportional to the square of the electric field, so that a plurality of ceramic piezoelectric elements 24 (32a, b) are connected in parallel to obtain a high electric field and energy density at the same voltage. . Thus, the oscillator 20 and the oscillator 30 overlap several sheets of thin ceramic piezoelectric elements 24 (32a, b) and connect the negative electrode plates 23a, 33a and the positive electrode plates 23b, 33b in parallel.

Next, a method for measuring elastic waves using the oscillator A, the detector B, and the ground control device C will be described.

In order to implement the present invention, two types of field information are required, which are the spatial location of the oscillator and the detector and the time required for passing the acoustic wave. The coordinates of each point are three-dimensional spatial coordinates due to the slope of the ground surface and the detection hole. However, in the present invention, since the ground is imaged in a two-dimensional plane, each point of three-dimensional coordinates is optimized to two-dimensional coordinates. The plane to be imaged composed of the changed two-dimensional coordinates is called an image plane. This algorithm consists of the image plane equation, the coordinate shift, and the algorithm needed to determine the outline of the coordinate axis rotation image plane.

The most important thing in a program for seismic tomography is to determine the kernel matrix of the data. Each element of the kernel matrix of data is the length of the propagation path segment in the influence shape of the corresponding pixel. The length of the propagation path segment is calculated from the length of the pixel boundary and the pixel midpoint. In the algorithm of the present invention, the length of the propagation path segment is calculated by the formula consisting of the coordinates of the pixel center, the influence shape characteristics, and the propagation path.

Backprojection is a non-repeating approximation method commonly used to create early models. That is, it is a technique of obtaining an initial solution (the physical property of each pixel) inputted to obtain the final solution. The reverse projection algorithm determines the average physical property values for each element in the propagation path.

The algorithm used for singular value decomposition uses SVDCMP from "Numerical Recipes"^<9> in Press (1989). It is a function that similarly transforms a data kernel matrix into a double diagonal matrix by using a householder transformation and then decomposes outliers by applying a QR algorithm.

The solution to the mixed decision problem is to estimate the model variable m ^est from the measured data. The process of estimating model variables by decomposing the data kernel matrix, G, into eigenvectors and singular value matrices is called comprehensive inversion. The solution obtained from the inversion is as follows.

m ^est = (V _p L ^-1 U ^t _p ) d

Where V _p and U _p are eigenvectors, not 'O' in the model and data space, and L ^-1 is the inverse of the diagonal outlier matrix. That is, 1 divided by the outlier of each diagonal. The equation is

m ^est = G ^-g d

Here, when G ^-g is as follows, it is called a composite associative matrix.

G ^-g (general inversion) = V _p L ^-1 U ^t _p

If existing information is available, the inversion can be applied to the data residual vector [dd ₀ ].

m ^est = m ₀ + G ^-g (d-Gm ₀ )

Where m ₀ is the model vector presented earlier. This section uses the m ₀ calculated by the inverse projection method for the approximation of the dead space model vector greater than the value of 'O' of the m ₀ to the nature.

In order to examine the feasibility of the direct inversion technique, we compare it with the algorithm of the iterative inversion technique. Verification uses an indoor model (FIG. 7). The tomography program (which is a program for imaging the seismic wave specially designed by the present inventor) was run and verified, and a model was prepared for continuous improvement. The model is made of fresh rock in concrete and crushed in cement-sand to reproduce isolated fractures in fresh rock. In order to evaluate the reconstruction capability of the image, a cross section with a simple water component can be planned. This model is constructed with the cement-sand cube centered in the concrete cube. In order to precisely measure the physical properties of this model, small cross-hole seismic wave tests were performed on the model, and specimens were fabricated and subjected to seismic test and compression test.

Properties of Model Material property concrete Cement-sand Unit weight (t / m ³ ) 2.3 1.55 V _p (m / sec) 4,000 2,000 V _s (m / sec) 2,350 810 υ 0.24 0.35

The experimental data were inputted to reconstruct the cross-sectional image of the model for test operation and verification. A hammer (produced by PCB) was used as a compression wave oscillator, a PCB 308C02 accelerometer as a sensor, and an HP 355670A signal analyzer as a recording device. Data collection generated a shock wave rich in P-wave energy with a hammer and measured the P-wave by reorienting the detector. Validated with P-wave measurement data.

FIG. 8 is a reconstructed image obtained by oscillation and oscillation respectively from the two sides facing each other like a cross hole, and FIG. 9 is a reconstructed image obtained by oscillation and oscillation from four directions as shown by CT. The fact is that if the data is measured in four directions, such as CT, the cross section can be almost completely reconstructed, but collecting data using the general cross-hole method applied to the ground has difficulty in reconstructing the complete cross section.

The inversion algorithm of tomography is largely classified into direct inversion technique and repetitive inversion technique. In order to understand the advantages and disadvantages of the two methods and to review the method that best fits the objectives of the present invention, a comparison between SIRT (Simultaneous Reconstruction Technique), which is a representative algorithm of the inverse projection method, the comprehensive inversion algorithm, and the iterative inversion technique is compared.

In order to evaluate the capability of the algorithm and SIRT of the present invention, the reconstructed images were compared from the data measured in the model. The number of pixels used in the present invention was 18 x 18 and the number of propagation paths, that is, the number of data, was 324. The BPT results were compared by combining three algorithms: direct inversion using initial data, repetitive inversion, and direct inversion using initial SIRT results. The direct inversion technique using the initial SIRT result is to examine whether there is a possibility to obtain a more accurate solution by using the initial data calculated by the SIRT instead of using the existing BPT result as the initial data.

In Fig. 10, the repetition method reconstructs the cross section of the cement-sand to some extent, but when the worst of the three methods and the number of repetitions exceeds a certain value, the sum of residuals representing the degree of convergence of the data no longer improves. . Therefore, the resulting image does not improve in proportion to the repetition number, so it is difficult to determine the repetition count required to reconstruct the best image. On the other hand, the result of direct inversion shows a better ability to reconstruct the cross section of the cement-sand and a stable image at a constant range of power values (in this case, 3 to 9). Using the BPT and SIRT results for the initial data does not show any difference in the quality of the images.

As a result, reconstructing the image using a direct inversion technique using BPT and singular value decomposition is considered to be the most suitable for the purpose of the present invention. A common phenomenon in this comparison review is that the abnormal signal band (cement-sand) portion is distorted in the radial direction of data measurement.

In FIG. 11, the above phenomenon is due to the visible phenomenon of the electron microscope resulting from the transmission angle of only 45 ° due to the geometrical arrangement of the data measurement. In order to solve this problem, it is necessary to reduce the visibility of electron microscope by increasing the transmission angle (θ) by making the depth of excavation of the detection hole deeper than the interval of the detection hole when applying the field.

Table 2 summarizes the comparative review of the direct and indirect inversion methods.

Algorithm Comparison technique Mathematical aspects Weakness Advantages Iteration "Row-Action" repeat Similar The image varies depending on the number of repetitions.It is difficult to determine the number of repetitions for which the best image is calculated. Memory capacity for easy calculation Direct law Complex of singular values Add existing information only in the most robust part Heavy calculation burden Purity of the solution, quantitative measurement possible

[Example of detection]

* Target site: Foundation ground of Dueum Bridge No. 3 of 10 tools between Yeongju-Jecheon and Jungang Expressway in Dueum-ri and Daebu-myeon, Danyang-gun, Chungcheongbuk-do.

This area is limestone, and yellowish brown clay and blue-gray limestone were interlocked with north-eastern headquarters and Seogyeongsa (N10E / 85NE) of piers. Depending on the location, the fractures were very severe within 10m to 20m from the base digging surface, and some showed common symptoms. S.I.G grouting with a 2.5mm spacing and a depth of 25m was used to reinforce the foundation prior to laying the foundation. The cross hole test was performed as part of the evaluation for grouting. Since the ground investigation before reinforcement was performed before the instrument of the present invention was invented, a direct comparison before and after grouting reinforcement is impossible, but it may be indirectly compared with the results of seismic survey using gunpowder / hydrophone.

* Inspection worker

12 is a layout of the detection hole for field measurement. After digging for direct foundation, a concrete slab of 20m × 20m × 1.5m was placed on the foundation ground and grouted, and then the detection holes (S, R) were drilled in the two corners of the slab and the central part of the long axis. The size of these detection holes S and R is NX, and the distance between the two detection spaces is preferably within 7 m for limiting the acoustic wave energy of the oscillator 22 and the oscillator 30 and measuring the shear wave. The test distance was set to 5m in consideration of the shear wave measurement. The oscillator (A) and the detector (B) connected their hooks (3) to the tip of the directional bar, and the oscillator (22) and the oscillator (30) were oriented so as to face each other and matched their height.

Because P-waves are the fastest, they can be measured to some degree without the need to reorient the oscillator and detector. It is possible to measure the arrival time of the P-wave by first starting the seismic recording. However, the speed of the S-wave is slower than that of the P-wave, which makes it difficult to identify the point of arrival of the S-wave when it overlaps with the excitation of the P-wave. To overcome these difficulties and obtain a seismic record that can identify the S-wave arrival point, the oscillation direction and the detector direction must be adjusted simultaneously. This fact can be proved by the following theoretical background and practical application experience.

That is, the point load acting in the direction x _j , and the displacement of the point separated by the distance r from X ₀ (t) is expressed by the following equation.

Where u is the displacement in the i direction, x is the position vector, X _i (i = 1,2,3) is the Cartesian coordinate, t is the time variable, ρ is the density, γ is the direction cosine, and δ _ij is the Kronecker delta. When i is j, δ _ij = 0 and when i ≠ j, δ _ij = 1, r is the distance between the oscillator and the detector, α is the compressed wave velocity, and X _{o (t)} is the point load (dynamic load).

This expression consists of three terms. The first term attenuates the amplitude r ^-2 under impact. The remaining term is attenuated to r ^-1 and the distance r increases, so most of the displacement is due to the second and third terms, and the first term is negligible. The first term is called the near-region term near the point load (r → 0), and the second term and the third term are called the far-region term at the far distance (r → 0).

In the seismic measurement, the measurement of the data is performed at a long distance, so the oscillation width is mainly a waveform consisting of the second and third terms. The second term is the far-area P-wave term, and the magnitude of the P-wave amplitude in each direction is shown in FIG. Here, the direction cosine between the load direction and the propagation path is represented by γ. When γ = 1, that is, when the load direction and the propagation direction are the same, the amplitude of the P-wave is the largest. In contrast, when γ = 0, that is, when the load direction and the propagation direction are orthogonal, the amplitude of the P-wave is "O". Therefore, to obtain good P-wave data, the propagation path and the axis of the detector must be matched to the point load direction. The third term is the far-region S-wave term, and the amplitude of each direction is as shown in FIG. γ 'is the direction cosine of the angle between the load direction and the axis of the detector (B). When γ '= 1 (the load direction and the axis of the detector coincide and the load direction and propagation path are orthogonal), the amplitude of the shear wave is measured the largest. In other words, in order to measure high-quality S-waves, the axis of the detector B should be installed on the propagation path perpendicular to the oscillation direction so as to coincide with the oscillation direction.

In FIG. 14, when compressed air is blown into the air bag 11 and inflated, the air bag 11 is inflated as shown by the reference numeral 11 ′ to bring the oscillator A and the detector B into close contact with the main surfaces of the detection holes S and R. The preparation is completed by connecting the cables 5a and 5b of the oscillator A and the detector B to the ground control device C.

The ground control device (C) consists of an electronic control unit for operating the oscillation and the receiver, and a compressed air control unit for operating the airbag.The electrical signals of the oscillation and the oscillation transmitted and received by the ground control unit (C) are controlled by a general oscilloscope or You can connect to a waveform analyzer and record it.

* Instrumentation

The P-wave measurement is performed by adjusting the direction such that the oscillator A and the detector B face each other with the oscillator 22 and the oscillator 30 facing each other. S-wave measurement is directed at the oscillator 22 towards the detector B, and the detector B pointing the oscillator 30 toward the propagation path, i.e., the oscillator 22, overcoming the subsequent vibration of the P-wave. The energy value of the S-wave is maximized and measured so that the S-wave arrival time point is clearly distinguished. Next, the reverse S-wave is measured by rotating the direction of the pendulum 30 at that position, and then the two S-waves are synthesized.

A high voltage is applied to the piezoelectric element 22a of the oscillator 22, an elastic wave (shock wave) is applied to the cavity wall of the detection hole S side of the oscillator (A), and the shock signal is recorded in a recording device (waveform analyzer) to determine the time of occurrence of the shock wave. Decide The detector B at the point when the acoustic wave (shock wave) starting from the empty wall of the detection hole S passes through the medium between the two detection holes S and R and reaches the empty wall of the detection hole R on the detector B side. The wavelength was measured and the wavelength was measured and recorded on the waveform analyzer. One phase of P-wave recording and S-wave recording was recorded on floppy diskette at one measurement point. This process was repeated up to 24m deep with 0.5m depth to record P-wave and S-wave.

* Determination of transit time

15 is a typical waveform of a P-wave. In the figure, the top waveform is the trigger waveform of the oscillator and the bottom waveform is divided into two parts to help understand when the P-wave reaches the detector (B). The initial straight line portion and one cycle signal on the left side are electrical signals generated by the ground coupling device C cross coupling by the impact signal of the oscillator A. FIG. The straight portion extending beyond this cross coupling has yet to reach the detector B, although the P-wave energy has started from the oscillator A. The second part of the signal is the recording of various waves such as the excitation wave and the reflected wave of the P-wave after the straight line ends and the first P-wave arrives. "T" marked on the trigger signal of the oscillator A is the point at which the shock wave starts in the oscillator A, and "P" on the oscillator signal is the point at which the P-wave reaches the oscillator. The elapsed time between "P" and "T" is the time taken for the P-wave to pass the distance between the detection holes.

16 is a waveform of the measured S-wave. In this figure, (A) is the waveform of the shear wave recorded with the oscillator (A) and the detector (B) facing the same direction. "S" indicates the point of arrival of the S-wave. (B) is reverse S-wave measured by reversing the direction of detector B. Combining the output at the time point "S" in the opposite direction with respect to the signal (A) as shown in (C), the signal at the time of reaching the S-wave looks like a butterfly. According to such a synthesis method, the S-wave arrival time can be read more concisely. The elapsed time between " T "and " S " is the time taken for the S-wave to reach the detection hole D for the oscillator after starting the detection hole C for the oscillator.

* Velocity calculation of seismic waves

P-wave and S-wave velocities, Poisson's ratios, and modulus of elasticity are calculated from the measured transit times of the P-wave and S-wave.

V _p = pass distance / P-wave pass time

V _s = passing distance / S-wave passing time

G = (γ / g) V _s ²

M = (γ / g) V _p ²

υ = [0.5 (V _p / V _s ) ² -1] / ((V _p / V _s ) ² -1]

Where V _p is the P-wave velocity, V _s is the S-wave velocity, G is the shear modulus, M is the constraint modulus, and υ is the Poisson's ratio.

Fig. 17 shows the velocity and Poisson's ratio of the seismic wave by the depth of the detection hole. In this figure, the P-wave and S-waves are 3000m / sec and 1800m / sec at depths of 0 to 10m, and P-wave and S are less than 60m. The fact that the wave speeds are 6000 m / s and 3000 m / s shows that this foundation is two layers. Poisson's ratio was about 0.35.

* Evaluation of grouting performance

The ground survey before reinforcement is the result of seismic survey using gunpowder / hydrophone, which is inconsistent with the measurement result according to the present invention, but the closest side view is the side line (BH4-BH1, BH5-BH2) of FIG. . The velocity distribution of P waves for each depth measured using the gunpowder / hydrophone and the oscillator A and the detector B of the present invention is shown in FIG. 18. Although the sidelines are different and the equipment used is different, it is clear that the speed of the P-wave is increased by the grouting.

As a goal is to develop a tomography for estimating the properties of earthworks design, S-wave measurement as well as P-wave is necessary. By estimating the constrained modulus and shear modulus respectively from P-wave and S-wave measurements, more complete design properties can be obtained. The piezoelectric measuring instrument of the present invention can meet these technical requirements, the biggest advantage is that by adjusting the direction of the detector can accurately measure the S-wave that has not been able to measure until now, using high frequency, high-quality data It can be used in general NX detector. In particular, the airbag can be closely attached to the detection hole wall, so it can be used not only for the vertical detection hole but also for the detection hole that is inclined or horizontally perforated, and thus it is possible to estimate the rock property values behind the ceiling and the side wall of the underground space such as a tunnel. However, this instrument has a relatively small energy and uses a high frequency, so it is pointed out that the irradiation distance is short. However, the measurement distance can be extended by overlapping the acoustic wave signals to increase the signal-to-noise ratio.

In addition, it is thin, compact and lightweight, and its structure is simple for measurement in the forging hole and NX detection hole, and it is easy to perform measurement and maintenance.The precise trigger control circuit enables the increase of the average signal-to-noise ratio of the time band waveform. Measured values can be obtained.

The seismic measuring instrument of the present invention can be widely used for quality control and soundness evaluation of various basic civil works such as cast-in-placement piles and concrete structures.

Claims (2)

The circuit board cylinder 5 with the circuit board is suspended from the bottom of the string board 2 with the hook 3 attached to the center of the upper surface thereof, and a pair of cable tubes 8a, b) and at the same time, the band support 9 and the oscillating suspension suspension 10 are attached to one side of the bottom surface of the bottom cover 7, and the ceramic piezoelectric element 24 is attached to the lower end of the suspension suspension 10. And the oscillator 20 for accommodating the acoustic wave oscillation in which the oscillator 22 in which the cathode plates 23a and the cathode plates 23b are sequentially laminated and bonded together with the oscillators 22 connected to the cathodes of the electrode plates is attached to the housing 21. Put the band cup 26 loaded with the compression spring 25 on the bottom ram 21d of the head) and fix it with the band 12 over the fabric air bag 11 between the band support 10 and the compressor. The end of the air supply pipe 4 connected to the side is connected to the air bag 11, and the external cables 5a and b are organically connected to the negative electrode plate 23a and the positive electrode plate 23b. A faulty acoustic wave oscillator A; The circuit board cylinder 5 with the circuit board is suspended from the bottom of the string board 2 with the hook 3 attached to the center of the upper surface thereof, and a pair of cable tubes 8a, b) and at the same time, the band support 9 and the suspension suspension for oscillating body 10 are attached to one side of the bottom surface of the bottom cover 7, and the thin ceramic piezoelectric element 32a, the negative electrode plate 33a and the thick ceramic piezoelectric body are attached. The element 32b, the positive electrode plate 33b, the thin ceramic piezoelectric element 32a, the positive electrode plate 33b, the thick ceramic piezoelectric element 32b, the negative electrode plate 33a, and the thin piezoelectric element 32a are stacked in this order. A band in which the receivers 30 connected to each other are housed in the housing 21 and attached to the lower end of the suspension span 10, and the compression spring 25 is loaded on the bottom ram 21d of the housing 21. Put on the cup 26 and span the fabric air bag 11 between it and the band support 9. It is fixed by the band 12, the end of the air supply pipe (4) connected to the compressor side is connected to the air bag 11, the external cables (5a, b) and the negative electrode plate (33a) of the receiver 30 An acoustic wave measuring instrument comprising an acoustic wave detector (B) organically connected to a positive electrode plate (33b). Drill at least one pair of equally-sized detection holes at positions opposite to each other, and install an acoustic wave oscillator with a ceramic piezoelectric element oscillator at one side of the detection hole, and install an acoustic wave detector with a ceramic piezoelectric element oscillator at the opposite side of the detection hole. In the method of oscillating a seismic wave by applying a high voltage to the oscillator while the cable of the oscillator and the detector is connected to the ground control device, and oscillating the seismic wave to measure the P-wave, the detector faces the oscillator and the receiver. A method of measuring a shear wave using an acoustic wave, characterized in that the S-wave is measured by oscillating the elastic wave of the oscillator, and the two S-waves are synthesized after measuring the inverse S-wave while the oscillator is made with the oscillator back.