RU53458U1 - RADIO-RECEIVING RECORDING DEVICE FOR REMOTE DETERMINATION OF MECHANICAL PROPERTIES OF BOTTOM AND PALLET SEDIMENTS (OPTIONS) - Google Patents

Abstract

The utility model relates to acoustic location systems, in particular, intended for continuous measurement and indication during seismic acoustic studies in shallow water areas while studying the geological structure of the medium with the subsequent determination of the physicomechanical properties of bottom and bottom sediments (rocks) from a moving vessel. The objective of the utility model is to reduce the influence of electrical noise, the influence of waves of the aquatic environment and increase the dynamic range of the recording. The receiving-emitting recording device for remote determination of the mechanical properties of bottom and bottom sediments comprises a recorder, a radiating unit, a receiving unit containing at least one seismic sensor, a timer for setting the time interval between the supply of successive pressure pulses directly during the passage of the studied section of the profile and a command to record a seismic trace by a registrar, an analog-to-digital converter, while the input of the recorder is connected to the output of an analog-to-digital at least one matching device, while the input of the matching device is connected to the seismic sensor, and the output is connected to one of the inputs of the analog-to-digital converter, the recorder clock input is connected to the timer output, and the recorder's clock output to the analog-to-digital converter clock input, second output a timer connected to the input of the radiating unit. Examples of receiving and recording devices for remote determination of the mechanical properties of bottom and bottom sediments and the receiving unit are given.

Description

The utility model relates to acoustic location systems, in particular, intended for continuous measurement and indication during seismic acoustic studies in shallow water areas while studying the geological structure of the medium with the subsequent determination of the physicomechanical properties of bottom and bottom sediments (rocks) from a moving vessel.

The well-known "sonar for recognition of sea soils" (patent RU 2045081 C1, publ. 1995.09.27), which contains an echo sounder, a receiving path, a subtraction circuit, a pulse shaper, an echo extension meter and an indicator. In addition, two coincidence schemes, a pulse generator, a linear-frequency-modulated signal generator and a counter are introduced into the sonar, thereby increasing the accuracy of determining the parameters of the reflecting boundary, increasing the reliability of the measurement results, improving the reliability of detecting objects with reflective characteristics different from the boundary and determining location of the border.

The disadvantage of this invention is the presence of electrical noise, the influence of waves of the aquatic environment and the small dynamic range of the recording.

Known "Navigation system" (patent RU 2121133, publ. 1998.10.27), in which the receiving-emitting device is made in the form of a seismic station with pneumatic sources and end buoy, seismicity, while the first input and outputs of the seismic station are connected to a computer. In addition, it is equipped with a timer for recording and adjusting the time interval between the supply of successive seismic signals directly during the passage of the studied section of the profile, the input of which is connected to the output of the computer.

The invention is aimed at providing the ability to adjust the time interval between the supply of successive seismic signals directly during the passage of the studied section of the profile, as well as to continue to work when the control computer restarts in the event of a freeze or failure.

This invention is the closest analogue of the claimed invention, i.e. prototype.

The disadvantage of this invention is the presence of electrical noise, the influence of waves of the aquatic environment and the small dynamic range of the recording.

The main technical problem, which the proposed utility model is aimed at, is to reduce the influence of electrical noise, the influence of waves of the aquatic environment and increase the dynamic range of the recording.

This problem is solved by creating a receiving-emitting recording device for remote determination of the mechanical properties of bottom and bottom sediments, including a recorder, a radiating unit, a receiving unit containing at least one seismic sensor, a timer for setting the time interval between the supply of successive pressure pulses directly during passing the studied section of the profile and the command to record the seismic trace by the registrar, analog-to-digital converter, with

the input of the recorder is connected to the output of the analog-to-digital converter, in which the receiving unit further comprises at least one matching device, while the input of the matching device is connected to the seismic sensor, and the output is connected to one of the inputs of the analog-to-digital converter, the sync input of the recorder is connected with the output of the timer, and the clock output of the recorder with the clock input of the analog-to-digital converter, the second output of the timer is connected to the input of the radiating unit.

In addition, the receiving unit contains at least 16 channels, including serially connected matching device and seismic sensor. In addition, the seismic sensor is made in the form of a piezoelectric receiver. The problem is also solved by creating a receiving and recording device for remote determination of the mechanical properties of bottom and bottom sediments, including a recorder, a receiving unit containing at least one seismic sensor, a timer for setting the time interval between the supply of successive pressure pulses directly during the passage of the studied section of the profile and a command to record the seismic trace by the registrar, an analog-to-digital converter, while the input of the recorder is connected to the output of the analog-digital a transducer in which the receiving unit contains a piezo-cutter connected in series, containing 16 linearly arranged cylindrical piezoelectric receivers and a 16-channel matching device, while the recorder input is connected to the output of an analog-to-digital converter, the corresponding inputs of the 16-channel matching device are connected to the corresponding piezoelectric receivers and the outputs are connected to the corresponding inputs of the analog-to-digital converter, the recorder clock input is connected to the timer output, and the clock recorder output is connected to the clock an analog-digital converter.

In addition, one of the parts of the sealed connector is located in the front of the piezo-squeegee, the other part of the connector is located on the towing cable for their separate transportation and storage.

The problem is also solved by creating a receiving unit containing at least one seismic sensor, into which at least one matching device is added, including an amplifier and a bandpass filter connected in series, while the amplifier input is connected to the seismic sensor, the amplifier output is connected to the input filter.

In addition, the seismic sensor is made in the form of a piezoelectric receiver.

The essence of the proposed utility model is illustrated by graphic materials.

Figure 1 presents a block diagram of a multi-channel receiving-emitting recording device.

Figure 2 presents a block diagram of a receiving unit.

Figure 3 presents an example of a schematic diagram of a matching device with a voltage converter.

The receiving-emitting recording device for remote determination of the mechanical properties of bottom sediments (Fig. 1) includes a recorder 5, an emitting unit 1, comprising a pressure pulse emitter 3, an electrical pulse generator 2, a timer 4 for setting a time interval between the supply of successive pressure pulses directly during passing the studied section of the profile and the command to record the seismic trace by the universal recorder 5, analog-to-digital Converter 6, the receiving unit 7, containing separating apparatus 8, seismic sensors 9, wherein the recorder input 5 connected to the output of analog-digital converter 6, the input of the matching device 8 connected to the seismic sensors 9, and the output is connected

with the corresponding input of the analog-to-digital converter 6 (ADC), the clock input of the recorder 5 is connected to the output of the timer 4, and the clock output of the recorder 5 is connected to the clock input of the analog-to-digital converter 6, the second output of the timer 4 is connected to the input of the emitting unit 1.

In addition, the seismic sensor 9 is made in the form of a piezoelectric receiver.

Power is supplied by a voltage converter 12

The receiving and recording device for remote determination of the mechanical properties of bottom sediments according to option 2 (Figs. 1, 2) includes a recorder 5, a timer 4 for setting the time interval between the supply of successive pressure pulses directly during the passage of the studied section of the profile and a command to record the seismic trace by the registrar 5, analog-to-digital Converter 6, the receiving unit 7 (Fig.2), containing a piezo cutter, representing 16 linearly arranged cylindrical piezoelectric receivers 9.1 ... 9.16, and 16 channels matching device 8, while the input of the recorder 5 is connected to the output of the analog-to-digital converter 6, the corresponding inputs of the 16-channel matching device 8 are connected to the corresponding piezoelectric receivers 9.1 ... 9.16, and the outputs are connected to the corresponding inputs of the analog-to-digital converter 6, sync input the recorder 5 is connected to the output of the timer 4, and the clock output of the recorder 5 is connected to the sync input of the analog-to-digital converter 6. Power is supplied using the voltage converter 12.

The problem is also solved by creating a receiving unit (figure 2), which contains at least one seismic sensor 9, one matching device 8, including a series-connected amplifier 10 and a band-pass filter 11, while the input of the amplifier 10 is connected to the seismic sensor 9, the output of the amplifier 10 is connected to the input of the filter 11.

Power is supplied by a voltage converter 12.

In addition, the seismic sensor 9 is made in the form of a piezoelectric receiver.

Figure 3 shows an example of the execution of the matching device, where, using the elements LM78L05_SO8 (AD1) and LM78L05_SO8 (AD2), the power of the matching device is provided, which consists of a pre-amplifier built on the basis of the AD622 chip (AD3) and a band-pass filter built on the basis of the dual amplifier OP297 (AD4).

The device according to options 1, 2, 3 works as follows.

A distinctive feature of the measurement of the proposed device is the attraction of the dynamic parameters of the reflected waves. The reflection coefficient (the ratio of the amplitude of the reflected wave to the amplitude of the incident wave) depends on the angle of incidence of the wave on the boundary between two half-spaces with different elastic properties. Elastic properties are understood as bulk compression moduli (K1, K2), shear moduli (μ1, μ2) and density (ρ1, ρ2), as well as quantities derived from the above - longitudinal wave velocity (Vp1, Vp2), shear wave velocity (Vs1 , Vs2), Poisson's ratio (v1, v2). The dependence of the reflection coefficient on the angle is usually approximated by a dependence of the form R (θ) = Ro + Gr * sin ² (θ), where Ro and Gr are the coefficients depending on the ratio of the elastic properties of the two contacting media. (In our case, these media are water and bottom sediments). The dependence R (θ) is obtained as a result of a field experiment (after introducing all the necessary corrections into the field data), which, in turn, is approximated by a linear dependence with the corresponding Ro and Gr. Since the elastic moduli of the upper medium (water) are well known, it is possible to pass from Ro and Gr to the properties of the lower medium (bottom sediments). In addition, using observations in a wide range of incidence angles (which is equivalent to a wide range of distances between the source of elastic

waves and the receiver), you can directly determine the critical angle (analog of the angle of total internal reflection in optics) by a sharp increase in the amplitude of the reflected wave near it, if the velocity of longitudinal waves in bottom sediments is greater than the velocity of longitudinal waves in water (and this is usually done). This gives additional information about the velocity of longitudinal waves of bottom sediments and reduces the ambiguity in determining the elastic moduli of bottom ones.

To set the time interval between the supply of successive pulses directly during the passage of the studied section of the profile and the command to record the seismic trace by timer 4, a synchronizing start pulse is generated, sent to the recorder 5, as well as a command to start the electric pulse generator 2, which supplies a signal to the pressure pulse emitter 3 The pulses emitted by the emitter of pressure pulses 3 probe the investigated section of the bottom and, being reflected, are received by the receiving device 7. Seismic sensors 9, Arranged in the seismic wave, they generate an electrical signal depending on the received seismic signal. Next, the electrical pulses from the seismic sensors 9 through a multi-channel matching device 8, designed for filtering and amplifying the signal, and containing pre-amplifiers 10 and band-pass filters 11 having a passband of 40-2000 Hz, are fed to an analog-to-digital converter 6. Final processing and recording of the signal is made in the registrar 5. To synchronize the start of operation of the analog-to-digital converter 6, the registrar 5 supplies a clock to the sync input of the analog-to-digital converter 6.

Seismocosa represents 16 linearly arranged cylindrical piezoelectric sensors, for example, of the Geopoint type manufactured by Benthos (USA). Each sensor represents a separate recording channel. Distance

between adjacent sensors - 2 m., i.e. the length of the active zone of the piezocosa is 30 m.

The receiving device containing the piezoelectric receivers and matching device is enclosed in a polyurethane reinforced hose poppies REINFORCED PU TUBING RPU. Hose inner diameter 19 mm, outer 26 mm. Dignity - does not lose elasticity at low temperatures. The total length of the polyurethane hose is 35 m, the active part is located exactly in the middle of the hose, i.e. the distance from the front edge of the hose to the 1st channel and from the 16th channel to the rear edge is 2.5 m.

In the front part of the seismic skid has one of the parts of the sealed connector, the housing of which is made of stainless steel. The other part of the connector is located on the tow cable. Those. The seismic cable and the tow cable can be transported and stored separately. In the back there is a metal plug, to which a nylon file can be attached to stabilize the position of the piezo during towing.

Spit filler is a non-conductive liquid, which can be used edible vegetable little. To ensure neutral buoyancy, lead weights are located along the entire length of the piezo-braid. The amount and weight of which is determined by the dry weight of the piezoelectric torch and the weight of the filler.

For towing seismic streamers in marine seismic exploration, special towing cables with a metal or Kevlar amplifier are used. So you can use a cable brand Teldor FTP, 25 pairs, category 5, PVC, used for laying external cable networks. The cable ends with a multi-pin radio connector for connection to a matching device.

Pre-amplifiers and filters are made in the form of a single unit on an open circuit board and are located in front of the piezo-plow.

The matching device is intended for

1. The transmission of signals from the channels from the towing cable to the input of the ADC through the connecting cable.

2. The supply of a stabilized bipolar supply voltage of ± 9 V. to the block of pre-amplifiers and filters in the piezocet through a towing cable.

3. Pre-amplification and filtering of signals from seismic sensors.

The power of the matching device is carried out either from any 12 V battery or from a 220/12 V network adapter. Consumption of the matching device is not more than 250 mA.

The matching device can be made on the basis of integrated amplifiers, for example, AD622, OP297 and using integrated voltage stabilizers, for example, LM78L05_SO8 and LM78L05_SO8, the matching device is powered, which consists of a preliminary amplifier built on the basis of the AD622 chip (AD3), as well as based microprocessor technology.

The ADC is designed to digitize an analog signal, while the bit depth can be 14 bits, and the maximum conversion frequency is 400 kHz. As an ADC, an external L-Card E-14-440 device connected to the recorder via a USB port can be used.

A universal recorder implements visualization of the received seismic signal, controls the operation of the ADC, enters the received signal onto a long-term storage medium in a given recording format. The registrar is running

based on microprocessor technology and can be made in the form of a specialized programmable computer (HEWLETT PACKARD 8940 V Multiprogrammer), the main function of which is to collect information from relevant sensors and transmit control signals to an analog-to-digital converter, as well as in a mobile version based on a laptop brand computer Fujitsu with a clock frequency of 1.8 GHz.

The introduction of a matching device into the receiving unit allows filtering and amplification of signals received from seismic sensors located in the immediate vicinity, and only then transmit a useful signal through a cable for subsequent processing by equipment placed on board the vessel or shore, thereby reducing the effect of electrical noise and increase the dynamic range of the recording.

Also, the transmission of already amplified signals by cable from the matching device to the analog-to-digital converter and the recorder allows you to apply a special research technique, which consists in deepening the piezo-cutter by 30-50 meters, which reduces the effect of interference associated with surface noise, for example, caused by water waves , and reduces the effect of the water-air boundary on the duration of the useful signal, which increases the accuracy of the measurement.

Claims (7)

1. The receiving-emitting recording device for remote determination of the mechanical properties of bottom sediments, including a recorder, a radiating unit, a receiving unit containing at least one seismic sensor, a timer for setting the time interval between the supply of successive pressure pulses directly during the passage of the studied section of the profile and a command to record the seismic trace by the recorder, an analog-to-digital converter, while the input of the recorder is connected to the output of the analog-to-digital converter A device, characterized in that the receiving unit further comprises at least one matching device, while the input of the matching device is connected to the seismic sensor, and the output is connected to one of the inputs of the analog-to-digital converter, the clock input of the recorder is connected to the output of the timer, and the clock output of the recorder - with the sync input of the analog-to-digital converter, the second timer output is connected to the input of the radiating unit. 2. The receiving-emitting recording device for remote determination of the mechanical properties of bottom sediments according to claim 1, characterized in that the receiving unit contains at least 16 channels, including a matching device and a seismic sensor connected in series. 3. The receiving-emitting recording device for remote determination of the mechanical properties of bottom sediments according to claim 1, characterized in that the seismic sensor is made in the form of a piezoelectric receiver. 4. A receiving and recording device for remote determination of the mechanical properties of bottom sediments, including a recorder, a timer for setting the time interval between the supply of successive pressure pulses directly during the passage of the studied section of the profile and a command to record the seismic trace by the registrar, an analog-to-digital converter, and the input the recorder is connected to the output of the analog-to-digital Converter, characterized in that the receiving unit contains a piezocos connected in series y containing 16 linearly arranged cylindrical piezoelectric receivers and a 16-channel matching device, while the recorder input is connected to the output of the analog-to-digital converter, the corresponding inputs of the 16-channel matching device are connected to the corresponding piezoelectric receivers, and the outputs are connected to the corresponding inputs of the analog-digital converter, the recorder clock is connected to the timer output, and the recorder clock is connected to the analog-digital converter clock. 5. The receiving and recording device for remote determination of the mechanical properties of bottom sediments according to claim 4, characterized in that one of the parts of the hermetic connector is located in the front part of the piezo cutter, the other part of the connector is located on the tow cable for their separate transportation and storage. 6. A receiving unit comprising at least one seismic sensor, characterized in that at least one matching device is included in it, including an amplifier and a bandpass filter connected in series, wherein the amplifier input is connected to the seismic sensor and the output is connected with filter input. 7. The receiving unit according to claim 6, characterized in that the seismic sensor is made in the form of a piezoelectric receiver.