CN107436448B - Engineering seismic exploration system and data reading system - Google Patents

Abstract

The invention discloses an engineering seismic exploration system and a data reading system. Engineering seismic exploration system: the monitoring system comprises a seismic wave detection device, a GPS time service storage device and a monitoring center, wherein seismic wave signals are collected through the seismic wave detection device to obtain seismic wave data; the GPS time service storage device is used for receiving satellite time service, storing seismic data and time service time corresponding to the stored data, and the monitoring center is used for monitoring the working states of the GPS time service storage device and the seismic detection device in a wireless mode and setting parameters for data acquisition. The engineering seismic exploration system receives satellite time service through the GPS time service storage device and stores seismic data acquired by the seismic wave detection device and corresponding time, so that the real-time performance of the seismic wave data is guaranteed, data transmission in a wired mode is not needed, and the complexity of engineering seismic exploration is reduced.

Description

Engineering seismic exploration system and data reading system

Technical Field

The invention relates to the field of seismic exploration, in particular to an engineering seismic detection system and a data reading system.

Background

The seismic exploration method is one of the earliest and most widely applied methods in geophysical exploration. The geophysical prospecting method is a geophysical prospecting method which utilizes the phenomena of reflection, refraction and the like of waves generated at the interface of media due to the difference of wave impedance of different media, and people can obtain the distribution state and physical property parameters of an underground medium (geologic body) by receiving the information of the reflected waves and the refracted waves. At present, the seismic exploration method is still the main means for oil exploration, natural gas exploration, coal exploration and engineering exploration on land and sea.

Engineering seismic exploration plays an extremely important role as an effective method for searching the fields of blind faults, geological structure exploration, engineering geological investigation and evaluation, tunnel advanced prediction and the like. As the engineering application often encounters complex conditions of geological background and terrain and features, the engineering seismic exploration instrument is required to have higher resolution and anti-interference capability, and the requirements on construction convenience and low cost of seismic data acquisition are higher.

The traditional engineering seismic exploration instrument adopts a wired online mode, and the seismic data acquisition amount is large, so that a large amount of human resources are occupied by the retraction and the release of a transmission line from a wave detector to a data acquisition instrument vehicle through a transmission cable. In addition, the seismic data transmission line has more hardware joints, so that the line communication checking work is very complicated. In particular, when the construction is performed in a medium and large city area, the wired connection mode objectively hinders the improvement of the work efficiency due to the limitation of the site environment. In suburban construction, the limitation of landform and land features (hillside, river, highway, railway, building, etc.) and data transmission distance is limited, and the limitation of online synchronous construction in a wired mode is more and more obvious, so that people are prompted to pay more attention to research an engineering seismic data acquisition instrument which does not need online synchronous in a wired mode, and the convenience of construction and the low cost are improved.

Disclosure of Invention

The invention aims to provide an engineering seismic detection system and a data reading system in order to conveniently realize seismic data acquisition and transmission at low cost without online synchronization in a wired mode so as to reduce the complexity of seismic data acquisition and processing.

In order to achieve the purpose, the invention provides the following scheme:

an engineering seismic detection system comprises a seismic wave detection device, a GPS time service storage device and a monitoring center;

the seismic wave detection device is correspondingly connected with the GPS time service storage device and is used for acquiring seismic wave signals, acquiring seismic wave data and sending the seismic wave data to the GPS time service storage device;

the GPS time service storage device is also in wireless connection with the monitoring center and is used for receiving and storing the seismic wave data and time service time corresponding to the seismic wave data acquisition, acquiring working state information of the seismic wave detection device and the GPS time service storage device and sending the working state information to the monitoring center;

the monitoring center is used for receiving and displaying the working state information, receiving control parameters set by a user and sending the control parameters to the GPS time service storage device;

and the GPS time service storage device is also used for controlling the seismic wave detection device according to the control parameters sent by the monitoring center.

Optionally, the seismic wave detection device includes a geophone string and a data acquisition station;

the geophone string is connected with the data acquisition station and used for detecting seismic wave signals and sending the seismic wave signals to the data acquisition station;

the data acquisition station is connected with the GPS time service storage device and is used for acquiring seismic wave signals sent by the geophone string to obtain seismic wave data and transmitting the seismic wave data to the GPS time service storage device.

Optionally, the geophone string is formed by connecting a plurality of geophones in series, each geophone corresponds to one ID number, and the geophone string sends the seismic wave signal and the ID number of the geophone generating the seismic wave signal to the data acquisition station.

Optionally, the data acquisition station includes: a data editor and a data transmitter;

the data editor is respectively connected with the geophone string and the data transmitter and is used for converting and editing seismic wave signals acquired by the geophone with an ID number according to the ID sequence to obtain seismic wave data and sending the seismic wave data to the data transmitter;

the data transmitter is connected with the GPS time service storage device and used for transmitting the seismic wave data to the GPS time service storage device for storage.

Optionally, the GPS time service storage device includes a GPS time service module, a data transmission port, a storage disk, a data acquisition controller, and an antenna;

the data transmission port is respectively connected with the seismic wave detection device and the storage disc; the data port is used for receiving seismic wave data acquired by the seismic wave detection device and sending the seismic wave data to the storage disc;

the GPS time service module is connected with the data acquisition controller and is used for receiving the time service time of a satellite and sending the time service time to the data acquisition controller;

the data acquisition controller is connected with the storage disk and is used for receiving the time service time sent by the GPS time service module and controlling the storage disk to store the seismic wave data sent by the data transmission port and the time service time corresponding to the time when the seismic wave data are received;

the data acquisition controller is wirelessly connected with the monitoring center through an antenna and used for acquiring working state information of the GPS time service storage device and the seismic wave detection device and sending the working state information to the monitoring center through the antenna.

Optionally, the monitoring center includes a monitoring module and a wireless control manager;

the monitoring module is connected with the wireless control manager and is used for receiving control parameters set by a user and sending the control parameters to the wireless control manager;

the wireless control manager is connected with the GPS time service storage device through an external antenna, and is used for sending the control parameters received by the monitoring module to the GPS time service storage device, receiving the working state information sent by the GPS time service storage device and sending the working state information to the monitoring module;

the monitoring module is also used for displaying the working state information sent by the wireless control manager.

An engineering seismic exploration data reading system is used for reading the engineering seismic exploration system and comprises a GPS time service data reading editor and a data management center;

the GPS time service data reading editor is respectively connected with the data management center and the plurality of GPS time service storage devices in the engineering seismic exploration system, and is used for automatically reading and editing the seismic wave data stored in the GPS time service storage devices and the time service time corresponding to the seismic wave data in batches according to time nodes at one time and sending the time service time to the data management center;

and the data management center is used for receiving an instruction input by a user, sending the instruction to the GPS time service data reading editor, and managing and storing the seismic wave data and the time service time corresponding to the seismic wave data.

Optionally, the GPS time service data reading editor includes a plurality of data download ports, a network cable port, and a data reading controller;

the plurality of data downloading ports are connected with the plurality of GPS time service storage devices in a one-to-one corresponding manner;

the data reading controller is respectively connected with the data management center and the plurality of data downloading ports, and is used for receiving an instruction sent by the data management center and controlling the plurality of data downloading ports to automatically read and edit the seismic wave data in the plurality of GPS time service storage devices and the time service time corresponding to the seismic wave data in batches according to time nodes;

the network cable port is connected with the data management center through a network cable; and the network cable port is used for sending the seismic wave data which are automatically read and edited at one time in batches according to time nodes and the time service time corresponding to the seismic wave data to the data management center through the network cable.

According to the specific embodiment provided by the invention, the invention discloses the following technical effects:

the invention discloses an engineering seismic detection system and a data reading system, wherein the engineering seismic detection system acquires seismic wave signals through a seismic detection device to obtain seismic wave data; the GPS time service storage device is used for receiving satellite time service, storing seismic data and time service time corresponding to the received seismic data, monitoring the working states of the GPS time service storage device and the seismic detection device in a wireless mode through the monitoring center, receiving control parameters set by a user, and sending the control parameters to the GPS time service storage device in a wireless mode. According to the engineering seismic exploration system, the GPS time service storage device receives the satellite time service, and the seismic data acquired by the seismic detection device and the corresponding time are stored, so that the real-time performance of the seismic data is ensured, the data do not need to be transmitted in a wired mode, and the complexity of engineering seismic exploration is reduced;

the data reading system automatically reads and edits the seismic wave data stored in the plurality of GPS time service storage devices in batch according to time nodes through the GPS time service data reading editor at one time and sends the data to the data management center.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

FIG. 1 is a block diagram of an engineered seismic exploration system according to the present invention;

FIG. 2 is a block diagram of a seismic wave detection device of an engineered seismic exploration system provided in accordance with the present invention;

FIG. 3 is a schematic diagram of the appearance and structure of a data acquisition station of an engineered seismic acquisition system according to the present invention;

FIG. 4 is a block diagram of an engineered seismic survey data reading system;

wherein, a is an appearance diagram of the data acquisition station, b is a structural schematic diagram of the data acquisition station; 201 is a data acquisition station, 202 is a detector string, and 203 is a detector; 301 is a power supply board, 302 is a data editor, 303 is a data transmitter, 304 is a GPS time service storage device port, and 305 is a 12V power supply interface; 401 is a data reading editor, 402 is a data management center, 403 is a data downloading port, 404 is a network cable port, and 405 is a data reading controller.

Detailed Description

The invention aims to provide an engineering seismic exploration system and a data reading system, which can conveniently realize seismic data acquisition and transmission at low cost under the condition of no need of online synchronization in a wired mode so as to reduce the complexity of seismic data acquisition and processing.

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in further detail below.

As shown in fig. 1, an engineering seismic exploration system includes a seismic wave detection device 101, a GPS time service storage device 102, and a monitoring center 103;

the seismic wave detection device 101 is correspondingly connected with the GPS time service storage device 102, and is used for acquiring seismic wave signals, acquiring seismic wave data and sending the seismic wave data to the GPS time service storage device;

the GPS time service storage device 102 is further wirelessly connected to the monitoring center 103, and the GPS time service storage device 102 is configured to receive and store the seismic wave data and time service time corresponding to the time service for acquiring the seismic wave data, acquire operating state information of the seismic wave detection device 101 and the GPS time service storage device 102, and send the operating state information to the monitoring center 103;

the monitoring center 103 is configured to receive and display the working state information, receive a control parameter set by a user, and send the control parameter to the GPS time service storage device 102;

the GPS time service storage device 102 is further configured to control the seismic wave detection device 101 according to the control parameter sent by the monitoring center 103.

Optionally, as shown in fig. 2, the seismic wave detection device 101 includes a geophone string 202 and a data acquisition station 201;

the geophone string 202 is connected with the data acquisition station 201, and the geophone string 202 is used for detecting seismic wave signals and sending the seismic wave signals to the data acquisition station 201;

the data acquisition station 201 is connected to the GPS time service storage device 102, and the data acquisition station 201 is configured to acquire seismic wave signals sent by the geophone string 202, obtain seismic wave data, and transmit the seismic wave data to the GPS time service storage device 102.

Optionally, the geophone string 202 is formed by connecting a plurality of geophones 203 in series, each geophone 203 corresponds to one ID number, and the geophone string 202 sends a seismic wave signal and simultaneously sends the ID number of the geophone 203 generating the seismic wave signal to the data acquisition station 201.

Optionally, the data acquisition station 201 includes: a data editor 302, a data transmitter 303;

the data editor 302 is respectively connected with the geophone string 202 and the data transmitter 303, and is used for converting and editing seismic wave signals acquired by the geophones with ID numbers according to the ID sequence to obtain seismic wave data and sending the seismic wave data to the data transmitter 303;

the data transmitter 303 is connected to the GPS time service storage device 102, and the data transmitter 303 is configured to transmit the seismic wave data to the GPS time service storage device 102 for storage.

Specifically, as shown in fig. 3, a is an external view of the data acquisition station 201, a housing of the data acquisition station 201 is made of a high-strength aluminum alloy material, and a b is a schematic structural view of the data acquisition station 201, where the data acquisition station 201 further includes: the power supply board 301 is used for boosting the voltage of the circuit in the acquisition station (the external connected direct current is boosted from 12V to 48V); a data editor 302 for converting and editing the digital seismic signals collected by the detectors attached with ID numbers according to the ID sequence; the data transmitter 303 is configured to transmit the edited digital signal from the GPS time service storage device port 304 to the GPS time service storage device 102 for storage, where the data acquisition station 201 includes four external connection ports, which are: the GPS time service storage device port 304, the 12V power interface 305 and 2 adjacent detector string interfaces are connected with the two detector strings 202.

Specifically, the geophone 203 includes a magnetic steel coil and a data conversion device, the magnetic steel coil is located at the lower end of the geophone, the analog-to-digital conversion device is located at the upper end of the geophone, the magnetic steel coil is connected with the analog-to-digital conversion device, the magnetic induction coil is used for detecting seismic wave analog signals and transmitting the seismic wave analog signals to the data conversion device, the data conversion device is connected with the data acquisition station 201, and the data conversion device is used for converting the seismic wave analog signals into digital seismic wave signals and transmitting the digital seismic wave signals to the data acquisition station 201.

Specifically, the invention divides 720 detectors into 20 strings, and each string has 36 detectors. Each detector is attached with an independent ID number (0-35) for managing detector sequencing. The detector string port is connected to the data acquisition station 201.

Optionally, the GPS time service storage device 102 includes a GPS time service module, a data transmission port, a storage disk, a data acquisition controller, and an antenna;

the data transmission port is respectively connected with the seismic wave detection device 101 and the storage disk; the data port is used for receiving seismic wave data acquired by the seismic wave detection device 101 and sending the seismic wave data to the storage disc;

the GPS time service module is connected with the data acquisition controller and is used for receiving the time service time of a satellite and sending the time service time to the data acquisition controller;

the data acquisition controller is connected with the storage disc and is used for receiving the time service time sent by the GPS time service module and controlling the storage disc to store the seismic wave data sent by the data transmission port and the time service time corresponding to the time service of receiving the seismic wave data;

the data acquisition controller is wirelessly connected with the monitoring center through an antenna, and is used for acquiring working state information of the GPS time service storage device 102 and the seismic wave detection device 101 and sending the working state information to the monitoring center through the antenna.

Specifically, the GPS time service storage device 102 is molded by casting with a grinding tool, and the housing is made of a strong plastic material. The strong plastic is poured and formed at one time to enhance the sealing performance of the shell, and the shell is not easy to damage.

Optionally, the monitoring center includes a monitoring module and a wireless control manager;

the monitoring module is connected with the wireless control manager and is used for receiving control parameters set by a user and sending the control parameters to the wireless control manager;

the wireless control manager is connected with the GPS time service storage device 102 through an external antenna, and is used for sending control parameters received by the monitoring module to the GPS time service storage device 102, receiving working state information sent by the GPS time service storage device 102 and sending the working state information to the monitoring module;

the monitoring module is also used for displaying the working state information sent by the wireless control manager.

Specifically, the monitoring module is a computer, monitoring software is installed on the computer, and the specific functions of the monitoring software include: (1) monitoring the working state of the GPS time service storage device 102; (2) setting parameters such as sampling interval, sampling duration, position editing of the GPS time service storage device 102 and the like of a system; (3) and loading a work area topographic map by combining GPS information, and searching the actual geographic position of the GPS time service storage device 102.

The wireless control manager includes: USB port, which is used to connect with the computer through USB line and receive various instructions sent by the exchange computer operating software, GPS port (2) which is used to receive satellite time service so as to synchronize with the time point of GPS time service storage device 102. (3) And the external antenna is used for realizing the mutual communication between the wireless control management device and the GPS time service storage device 102, receiving the working state information sent by the GPS time service storage device 102, sending the working state information to a computer through a USB port, and monitoring the working state by the computer through the monitoring software.

As shown in fig. 4, the invention further provides an engineering seismic exploration data reading system, which is used for reading the engineering seismic exploration system, and the engineering seismic exploration data reading system comprises a GPS time service data reading editor 401 and a data management center 402;

the GPS time service data reading editor 401 is connected to the data management center 402 and the plurality of GPS time service storage devices 102 in the engineering seismic exploration system, respectively, and the GPS time service data reading editor 401 is configured to automatically perform one-time reading and editing on the seismic wave data stored in each GPS time service storage device 102 and the time service time corresponding to the seismic wave data in batches according to time nodes, and send the time service time to the data management center 402;

the data management center 402 is configured to receive an instruction input by a user, send the instruction to the GPS time service data reading editor 401, and manage and store the seismic wave data and the time service time corresponding to the seismic wave data.

Optionally, the GPS time service data reading editor 401 includes a plurality of data download ports 403, a network cable port 404, and a data reading controller 405;

the plurality of data downloading ports 401 are connected with the plurality of GPS time service storage devices 102 in a one-to-one correspondence manner;

the data reading controller 405 is respectively connected with the data management center 402 and the plurality of data downloading ports 404, and the data reading controller 405 is configured to receive an instruction sent by the data management center 402, and control the plurality of data downloading ports 404 according to the instruction to automatically perform one-time reading and editing on the seismic wave data in the plurality of GPS time service storage devices 102 and the time service time corresponding to the seismic wave data in batches according to time nodes;

the network cable port 404 is connected with the data management center 402 through a network cable; the network cable port 404 is configured to send seismic wave data that are automatically read and edited at one time in batches according to time nodes and time service time corresponding to the seismic wave data to the data management center 402 through the network cable.

Specifically, the data reading controller 405 is further connected to the data management center 402, and is configured to receive a command from the data management center 402, control a plurality of data downloading ports according to the command from the data management center 402 in the same time period, and automatically transmit and unload the seismic wave data in the GPS time service storage device 102 at a time in a batch manner according to a time node;

specifically, the data management center 402 is a PC, and the PC is installed with data management software for playing back the seismic wave data and processing, editing, drawing, and outputting the seismic wave data.

According to the specific embodiment provided by the invention, the invention discloses the following technical effects:

the invention discloses an engineering seismic detection system and a data reading system, wherein the engineering seismic detection system adopts a GPS time service storage device, acquires the acquired data in real time through GPS time service, changes the traditional wired connection mode, and more flexibly adopts each GPS time service storage device to acquire and implement independent storage of seismic wave data; when seismic data are sorted in the later stage, the seismic data required by combination are screened through synchronous GPS time service information, and the seismic wave data in the GPS time service storage device are automatically unloaded and transmitted in a batch mode at one time according to time nodes through a GPS time service data reading editor, so that the construction difficulty of laying wired connection on field complex terrain ground features is reduced, the working efficiency is improved, and the seismic data precision is optimized.

The embodiments in the present description are described in a progressive manner, each embodiment focuses on differences from other embodiments, and the same and similar parts among the embodiments are referred to each other.

The principle and the implementation manner of the present invention are explained by applying specific examples, the above description of the embodiments is only used to help understanding the method of the present invention and the core idea thereof, the described embodiments are only a part of the embodiments of the present invention, not all embodiments, and all other embodiments obtained by a person of ordinary skill in the art based on the embodiments of the present invention without creative efforts belong to the protection scope of the present invention.

Claims (7)

1. An engineering earthquake detection system is characterized by comprising an earthquake wave detection device, a GPS time service storage device and a monitoring center;

the seismic wave detection device is correspondingly connected with the GPS time service storage device and is used for acquiring seismic wave signals, acquiring seismic wave data and sending the seismic wave data to the GPS time service storage device;

the GPS time service storage device is also in wireless connection with the monitoring center and is used for receiving and storing the seismic wave data and time service time corresponding to the seismic wave data acquisition, acquiring working state information of the seismic wave detection device and the GPS time service storage device and sending the working state information to the monitoring center;

the monitoring center is used for receiving and displaying the working state information, receiving control parameters set by a user and sending the control parameters to the GPS time service storage device;

the GPS time service storage device is also used for controlling the seismic wave detection device according to the control parameters sent by the monitoring center;

the GPS time service storage device comprises a GPS time service module, a data transmission port, a storage disk, a data acquisition controller and an antenna;

the data transmission port is respectively connected with the seismic wave detection device and the storage disc; the data transmission port is used for receiving seismic wave data acquired by the seismic wave detection device and sending the seismic wave data to the storage disc;

the GPS time service module is connected with the data acquisition controller and is used for receiving the time service time of a satellite and sending the time service time to the data acquisition controller;

the data acquisition controller is connected with the storage disk and is used for receiving the time service time sent by the GPS time service module and controlling the storage disk to store the seismic wave data sent by the data transmission port and the time service time corresponding to the time when the seismic wave data are received;

the data acquisition controller is wirelessly connected with the monitoring center through an antenna and used for acquiring working state information of the GPS time service storage device and the seismic wave detection device and sending the working state information to the monitoring center through the antenna.

2. The engineered seismic acquisition system of claim 1, wherein the seismic wave detection device comprises a geophone string and a data acquisition station;

the geophone string is connected with the data acquisition station and used for detecting seismic wave signals and sending the seismic wave signals to the data acquisition station;

the data acquisition station is connected with the GPS time service storage device and is used for acquiring seismic wave signals sent by the geophone string to obtain seismic wave data and transmitting the seismic wave data to the GPS time service storage device.

3. The engineered seismic exploration system of claim 2, wherein said geophone string is formed by connecting a plurality of geophones in series, each geophone corresponding to an ID number, said geophone string sending seismic signals while also sending ID numbers of geophones generating said seismic signals to said data acquisition station.

4. An engineered seismic acquisition system according to claim 2 or 3, wherein the data acquisition station comprises: a data editor and a data transmitter;

the data editor is respectively connected with the geophone string and the data transmitter and is used for converting and editing seismic wave signals acquired by the geophone with an ID number according to the ID sequence to obtain seismic wave data and sending the seismic wave data to the data transmitter;

the data transmitter is connected with the GPS time service storage device and used for transmitting the seismic wave data to the GPS time service storage device for storage.

5. The engineered seismic exploration system of claim 1, wherein said monitoring center comprises a monitoring module, a wireless control manager;

the monitoring module is connected with the wireless control manager and is used for receiving control parameters set by a user and sending the control parameters to the wireless control manager;

the wireless control manager is connected with the GPS time service storage device through an external antenna, and is used for sending the control parameters received by the monitoring module to the GPS time service storage device, receiving the working state information sent by the GPS time service storage device and sending the working state information to the monitoring module;

the monitoring module is also used for displaying the working state information sent by the wireless control manager.

6. An engineering seismic exploration data reading system, wherein the engineering seismic exploration data reading system is used for reading the engineering seismic exploration system as claimed in any one of claims 1 to 5, and comprises a GPS time service data reading editor and a data management center;

the GPS time service data reading editor is respectively connected with the data management center and the plurality of GPS time service storage devices in the engineering seismic exploration system, and is used for automatically reading and editing the seismic wave data stored in the GPS time service storage devices and the time service time corresponding to the seismic wave data in batches according to time nodes at one time and sending the time service time to the data management center;

and the data management center is used for receiving an instruction input by a user, sending the instruction to the GPS time service data reading editor, and managing and storing the seismic wave data and the time service time corresponding to the seismic wave data.

7. The system of claim 6, wherein the GPS time service data reading editor comprises a plurality of data download ports, a network cable port, and a data reading controller;

the plurality of data downloading ports are connected with the plurality of GPS time service storage devices in a one-to-one corresponding manner;

the data reading controller is respectively connected with the data management center and the plurality of data downloading ports, and is used for receiving an instruction sent by the data management center and controlling the plurality of data downloading ports to automatically read and edit the seismic wave data in the plurality of GPS time service storage devices and the time service time corresponding to the seismic wave data in batches according to time nodes;

the network cable port is connected with the data management center through a network cable; and the network cable port is used for sending the seismic wave data which are automatically read and edited at one time in batches according to time nodes and the time service time corresponding to the seismic wave data to the data management center through the network cable.

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