CN115561805A - Petroleum exploration vibration measurement module and monitoring system thereof - Google Patents

Abstract

The embodiment of the invention provides a petroleum exploration vibration measurement module and a monitoring system of the petroleum exploration vibration measurement module, and belongs to the technical field of petroleum exploration. The vibration measurement module includes seismic acquisition unit, power supply unit and memory cell, still includes: the device comprises a control unit, a displacement detection unit, a timing unit, a positioning unit and a communication unit, wherein the displacement detection unit, the timing unit, the positioning unit and the communication unit are connected with the control unit; the positioning unit is used for acquiring the position of the vibration measurement module in real time and generating position information; the communication unit is used for sending the position information to the server; the displacement detection unit is used for periodically detecting the displacement of the vibration measurement module and generating a displacement signal; the timing unit is used for sending a wake-up signal to the control unit according to a preset timing interval; the control unit is used for sending a starting signal to the positioning unit and the communication unit when receiving the awakening signal or determining that the vibration measuring module has continuous displacement based on the received displacement signal. The invention has the advantages of low energy consumption, convenient use, accurate positioning and avoidance of loss of the vibration measuring module.

Description

Petroleum exploration vibration measurement module and monitoring system thereof

Technical Field

The invention relates to the technical field of petroleum exploration, in particular to a petroleum exploration vibration measuring module and a monitoring system of the petroleum exploration vibration measuring module.

Background

In the process of oil exploration, seismic wave data generated by blasting needs to be collected so as to perform exploration of underground oil. In the prior art, thousands of seismic modules are arranged on the surface of the planned area to be surveyed and developed, wherein the seismic modules are arranged according to preset spacing distances and are used for acquiring seismic data in the area. The seismological measuring module is a closed box, the volume of the box is about 15cm < 10 cm >, and a data acquisition unit and an SD memory card are arranged in the box. However, in the using process, due to the fact that a planned area to be surveyed and developed is wide in region and long in surveying period, the seismic module is stolen, lost and the like and cannot be found back, seismic wave information collected by the seismic module is incomplete, a data chain is damaged, and the whole surveying effect is affected; in addition, the earthquake measuring module has high cost, and huge economic loss can be caused after the earthquake measuring module is stolen and lost.

Disclosure of Invention

The embodiment of the invention aims to provide a petroleum exploration vibration measuring module and a monitoring system thereof, which are used for solving the problems that in the using process, due to the fact that planned areas to be explored and developed are wide in regions and long in exploration period, seismic wave information collected by the seismic measuring module is incomplete, a data chain is damaged and the whole exploration effect is influenced because the seismic wave information collected by the seismic measuring module is damaged and the seismic wave information cannot be retrieved due to stealing and losing of the seismic measuring module; in addition, the earthquake measuring module has high cost, and can cause huge economic loss after being stolen and lost.

In order to achieve the above object, an embodiment of the present invention provides a vibration measurement module for petroleum exploration, where the vibration measurement module includes a seismic wave acquisition unit, a power supply unit, and a storage unit, the power supply unit is used to supply power to the seismic wave acquisition unit and the storage unit, and the vibration measurement module further includes:

the device comprises a control unit, a displacement detection unit, a timing unit, a positioning unit and a communication unit, wherein the displacement detection unit, the timing unit, the positioning unit and the communication unit are connected with the control unit;

the positioning unit is used for acquiring the position of the vibration measurement module in real time and generating position information;

the communication unit is used for sending the position information to a server;

the displacement detection unit is used for periodically detecting the displacement of the vibration measurement module and generating a displacement signal;

the timing unit is used for sending a wake-up signal to the control unit according to a preset timing interval;

the control unit is used for sending a starting signal to the positioning unit and the communication unit when the wake-up signal is received or when the vibration measurement module is determined to have continuous displacement based on the received displacement signal.

Optionally, the control unit is an MCU.

Optionally, the displacement detection unit is an acceleration sensor or a gyroscope.

Optionally, the petroleum survey vibration measuring module further comprises:

and the control unit is also used for sending a starting signal to the positioning unit and the communication unit and sending an alarm signal to the alarm unit at the same time.

Optionally, the alarm unit is an audible and visual alarm.

Optionally, the power supply unit is further configured to supply power to the displacement detection unit, the timing unit, the positioning unit, the communication unit, and the alarm unit.

Optionally, the communication unit includes: a Lora communication subunit and a 4G communication subunit;

the control unit is used for controlling the communication link to be switched between the Lora communication subunit and the 4G communication subunit according to the position of the vibration measuring module.

The invention also provides a monitoring system for a petroleum survey vibration measurement module, the system comprising:

a plurality of the vibration measuring modules are arranged at intervals in an oil surveying area;

the server is in communication connection with each vibration measurement module;

and the display unit is connected with the server and used for displaying the position information of the vibration measuring module.

Optionally, the system further includes:

the input unit is electrically connected with the server and used for receiving a control instruction of an operator for the vibration measurement module and generating a first external input signal corresponding to the vibration measurement module;

the server is also used for generating and sending a corresponding control signal to a corresponding vibration measuring module according to the first external input signal.

Optionally, the system further includes:

the mobile terminal is in communication connection with the server and is used for:

displaying the position information of the vibration measuring module;

receiving a control instruction of an operator for the vibration measurement module, and generating a second external input signal corresponding to the vibration measurement module;

the server is also used for generating and sending a corresponding control signal to a corresponding vibration measuring module according to the second external input signal.

According to the technical scheme, the vibration measuring module is prevented from being lost by arranging the positioning unit in the vibration measuring module to obtain the position of the vibration measuring module. Meanwhile, in order to reduce energy consumption and prolong the service time of the vibration measurement module, when the vibration measurement module normally collects seismic waves, the positioning unit and the communication unit are in a dormant state, and output signals of the timing unit and the displacement detection unit are used as trigger signals for starting working of the positioning unit and the communication unit, so that the energy consumption of the vibration measurement module is reduced while the position information of the vibration measurement module can be obtained, the service time of the vibration measurement module is prolonged, and the service life of the vibration measurement module is prolonged.

Additional features and advantages of embodiments of the invention will be set forth in the detailed description which follows.

Drawings

The accompanying drawings, which are included to provide a further understanding of the embodiments of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the embodiments of the invention without limiting the embodiments of the invention. In the drawings:

FIG. 1 is a schematic structural diagram of a first petroleum survey vibration measuring module provided by the invention;

FIG. 2 is a schematic structural diagram of a second petroleum survey vibration measurement module provided by the present invention;

fig. 3 is a schematic structural diagram of a monitoring system of a petroleum survey vibration measuring module provided by the invention.

Description of the reference numerals

1-a vibration measuring module; 2-a server; 3-a display unit;

4-an input unit; 5-a mobile terminal; 11-a seismic wave acquisition unit;

12-a power supply unit; 13-a storage unit; 14-a control unit;

15-a displacement detection unit; 16-a timing unit; 17-a positioning unit;

18-a communication unit; 19-an alarm unit; 181-Lora communication subunit;

182-4G communications subunit.

Detailed Description

The following detailed description of embodiments of the invention refers to the accompanying drawings. It should be understood that the detailed description and specific examples, while indicating embodiments of the invention, are given by way of illustration and explanation only, not limitation.

In the embodiments of the present invention, unless otherwise specified, the use of the directional terms such as "upper, lower, left, and right" generally refer to the directions or positional relationships shown in the drawings, or the directions or positional relationships that the products of the present invention are usually placed when in use.

The terms "first," "second," and the like are used solely to distinguish one from another and are not to be construed as indicating or implying relative importance.

The terms "parallel", "perpendicular", etc. do not require that the components be absolutely parallel or perpendicular, but may be slightly inclined. For example, "parallel" merely means that the directions are more parallel relative to "perpendicular," and does not mean that the structures are necessarily perfectly parallel, but may be slightly tilted.

The terms "horizontal", "vertical", "overhang" and the like do not imply that the components are required to be absolutely horizontal, vertical or overhang, but may be slightly inclined. For example, "horizontal" merely means that the direction is more horizontal than "vertical" and does not mean that the structure must be perfectly horizontal, but may be slightly inclined.

Furthermore, the terms "substantially", and the like are intended to indicate that the relative terms are not necessarily strictly required, but may have some deviation. For example: "substantially equal" does not mean absolute equality, but it is difficult to achieve absolute equality in actual production and operation, and certain deviations generally exist. Thus, in addition to absolute equality, "substantially equal" also includes the above-described case where there is some deviation. In this case, unless otherwise specified, terms such as "substantially", and the like are used in a similar manner to those described above.

In the description of the present invention, it should also be noted that, unless otherwise explicitly specified or limited, the terms "disposed," "mounted," "connected," and "connected" are to be construed broadly and may, for example, be fixedly connected, detachably connected, or integrally connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in a specific case to those of ordinary skill in the art.

FIG. 1 is a schematic structural diagram of a first petroleum survey vibration measurement module provided by the present invention; FIG. 2 is a schematic structural diagram of a second petroleum survey vibration measurement module provided by the present invention; fig. 3 is a schematic structural diagram of a monitoring system of the petroleum surveying vibration measuring module provided by the invention.

As shown in fig. 1, the present embodiment provides a vibration measurement module for petroleum exploration, where the vibration measurement module 1 includes a seismic wave acquisition unit 11, a power supply unit 12, and a storage unit 13, the power supply unit 12 is configured to supply power to the seismic wave acquisition unit 11 and the storage unit 13, and the vibration measurement module 1 further includes:

a control unit 14, and a displacement detection unit 15, a timing unit 16, a positioning unit 17 and a communication unit 18 connected to the control unit 14;

the positioning unit 17 is used for acquiring the position of the vibration measurement module 1 in real time and generating position information;

the communication unit 18 is used for sending the position information to the server 2;

the displacement detection unit 15 is used for periodically detecting the displacement of the vibration measurement module 1 and generating a displacement signal;

the timing unit 16 is configured to send a wake-up signal to the control unit 14 according to a preset timing interval;

the control unit 14 is configured to send a start signal to the positioning unit 17 and the communication unit 18 when receiving the wake-up signal or determining that the vibration measuring module 1 has continuous displacement based on the received displacement signal.

Specifically, in the present embodiment, the vibration measuring modules 1 are arranged in the survey area at intervals, typically, the vibration measuring modules 1 are spaced apart by about 40 meters from left to right and by about 100 meters from front to back, a seismic wave collecting unit 11 is arranged in the vibration measuring module 1 for collecting seismic wave propagation data during geological exploration, and a storage unit 13 is arranged for storing the seismic wave propagation data. In the embodiment, a control unit 14, a displacement detection unit 15, a timing unit 16, a positioning unit 17 and a communication unit 18 which are connected with the control unit 14 are arranged in the vibration measurement module 1, wherein the control unit 14 is in a real-time working state, and the control unit 14 is further used for controlling the seismic wave acquisition unit 11 to acquire seismic wave data; the positioning unit 17 that sets up can acquire the position of vibration measurement module 1 in real time and generate positional information, and send positional information to server 2 through communication unit 18, so that monitoring personnel can audio-visually obtain vibration measurement module 1's position through server 2, but because the particularity of vibration measurement module 1 during operation, place collection seismic wave data on the earth's surface promptly, at this moment, under no external force factor's influence, vibration measurement module 1 self can not produce the removal of position, consequently, let positioning unit 17 and communication unit 18 be in under the state of real-time work, the positional information who gathers be useless information, can lead to vibration measurement module 1 energy consumption big, and can reduce positioning unit 17 and communication unit 18 life, so when vibration measurement module 1 normally gathers seismic wave information, make positioning unit 17 and communication unit 18 be in the dormant state, in order to reduce the energy consumption.

In the present embodiment, the displacement detection unit 15 and the timing unit 16 are arranged to generate corresponding signals and send the signals to the control unit 14, so that the control unit 14 sends a start signal to the positioning unit 17 and the communication unit 18, and the positioning unit 17 and the communication unit 18 start to operate. Specifically, because the vibration measurement module 1 is in a field environment, there may be artificial theft and position change caused by animal collision, at this time, the displacement of the vibration measurement module 1 is detected by the arranged displacement detection unit, a displacement signal is generated and sent to the control unit 14, the control unit 14 performs displacement analysis, if the displacement obtained by analysis exceeds a preset threshold, it is indicated that the vibration measurement module 1 generates continuous displacement, positioning of the vibration measurement module 1 needs to be performed, and the displacement is sent to the server 2 through the communication unit 18, so as to ensure that a monitoring person can grasp the position information of the vibration measurement module 1 in real time at the server 2 end, and conveniently retrieve the vibration measurement module 1, meanwhile, in order to avoid false activation of the positioning unit 17 and the communication unit 18 due to animal false touch and the like, a mode of periodically detecting the displacement of the vibration measurement module 1 is adopted for judgment, if the displacement detection unit 15 collects a signal every 30 seconds, performs continuous n times of collection, the control unit 14 determines that the vibration measurement module 1 has all the displacement in the continuous n times of collection, it is indicated that the vibration measurement module 1 moves, the control unit 14 immediately starts the positioning signal and the positioning unit 17 and the positioning unit 18 perform communication; in addition, when seismic wave collection is performed, the number of the deployed vibration measurement modules 1 is large, and after the collection is completed, when the vibration measurement modules 1 are recovered, there may be a situation that the vibration measurement modules 1 cannot be rapidly and accurately recovered, but at this time, the vibration measurement modules 1 do not have displacement, so that the timing unit 16 needs to be set to send a wake-up signal for waking up the positioning unit 17 and the communication unit 18 to the control unit 14 after a preset timing interval passes, so as to help determine the position of the vibration measurement modules 1 to be recovered, specifically, the length of the preset timing interval is determined by a seismic wave collection period, for example: the seismic wave acquisition period is 200 hours, the preset timing interval can be set to 205 hours, timing is started only by the timing unit 16 after the arrangement of the vibration measurement module 1 is completed, and positioning display is performed after seismic wave data acquisition is completed.

Further, the control unit 14 is an MCU.

Specifically, a Micro Control Unit (MCU), also called a Single Chip Microcomputer (Single Chip Microcomputer) or a Single Chip Microcomputer (MCU), appropriately reduces the frequency and specification of a Central Processing Unit (CPU), and integrates peripheral interfaces such as a memory (memory), a counter (Timer), a USB, an a/D converter, a UART, a PLC, a DMA, and even an LCD driving circuit on a Single Chip to form a Chip-level computer, which performs different combination control for different applications.

Further, the displacement detecting unit 15 is an acceleration sensor or a gyroscope.

Specifically, in the present embodiment, the displacement detection unit 15 is provided as an acceleration sensor or a gyroscope. The acceleration signal of the vibration measurement module 1 is acquired through the acceleration sensor and is used as a displacement signal, the displacement signal is transmitted to the control unit 14, if the control unit 14 analyzes the displacement signal, the vibration measurement module 1 is judged to have a continuous acceleration signal, and the vibration measurement module 1 is illustrated in continuous movement, so that the displacement state of the vibration measurement module 1 is determined. Similarly, a gyroscope may be used for displacement determination, which is an angular motion detection device using a moment of momentum sensitive housing of a high-speed rotating body about one or two axes orthogonal to the rotation axis with respect to the inertial space. Angular motion detection devices made using other principles are also known as gyroscopes, which serve the same function.

As shown in fig. 2, further, the oil survey vibration measurement module 1 further includes:

and the alarm unit 19 is electrically connected with the control unit 14, and the control unit 14 is further configured to send an alarm signal to the alarm unit 19 while sending a start signal to the positioning unit 17 and the communication unit 18.

Specifically, in the embodiment, the alarm unit 19 is provided, and the control unit 14 sends the alarm signal to the alarm unit 19 while sending the start signal to the positioning unit 17 and the communication unit 18, so that the alarm unit 19 starts to operate, energy consumption can be reduced, and the service life of the alarm unit 19 can be prolonged, when the vibration measurement module 1 has displacement caused by theft, the alarm unit 19 can play a role in deterring and preventing the vibration measurement module 1 from being lost, and in addition, when the vibration measurement module 1 moves due to animal touch, animals can be driven by the alarm of the alarm unit 19; in addition, in the case of recovery, the vibration measuring module 1 that has not been recovered beyond the preset time interval can assist recovery by giving an alarm by the alarm unit 19 as a position indication.

Further, the alarm unit 19 is an audible and visual alarm.

Specifically, the audible and visual alarm can emit dazzling light and generate sound signals to alarm.

Further, the power supply unit 12 is also used for supplying power to the displacement detection unit 15, the timing unit 16, the positioning unit 17, the communication unit 18 and the alarm unit 19.

Specifically, the power supply unit 12 may adopt a rechargeable battery, and the amount of electricity stored in the battery can meet the usage time of 20-30 days; in addition, the solar panel is arranged on the vibration measuring module 1, and the solar panel is charged by utilizing light energy, so that the service time is prolonged.

Further, the communication unit 18 includes: a Lora communication sub-unit 181 and a 4G communication sub-unit 182;

the control unit 14 is used for controlling the communication link to switch between the Lora communication sub-unit 181 and the 4G communication sub-unit 182 according to the position of the vibration measuring module 1

Specifically, in the present embodiment, in order to reduce power consumption at the time of communication, lora communication and 4G communication are employed. More specifically, first, an electronic fence area is determined based on the location of the Lora communication base station, and the vibration measurement module 1 communicates with the server 2 through the Lora communication subunit 181 when located inside the electronic fence area, and communicates with the server 2 through the 4G communication subunit 182 when located outside the electronic fence area. Namely, the Lora communication mode is adopted in a short distance, the 4G communication is adopted in a long distance, and the energy consumption can be reduced to the maximum extent under the condition that the vibration measuring module 1 and the server 2 can normally communicate.

In another embodiment, the Lora communication sub-unit 181 and the 4G communication sub-unit 182 are designed as a redundancy, and when normal communication cannot be performed between the Lora communication sub-unit 181 and the server 2, the Lora communication sub-unit 182 communicates with the server 2, so that the reliability of the system is improved.

As shown in fig. 3, the second aspect of the present invention also provides a monitoring system for a petroleum survey vibration measurement module, the system comprising:

a plurality of the vibration measuring modules 1 are arranged at intervals in an oil surveying area;

the server 2 is in communication connection with each vibration measuring module 1;

and the display unit 3 is connected with the server 2 and used for displaying the position information of the vibration measuring module 1.

Specifically, in the process of petroleum exploration, a plurality of vibration measurement modules 1 are required to be arranged in an exploration area (100-150 square kilometers), so that a server 2 is arranged at a remote monitoring end to be in communication connection with each vibration measurement module 1, and a display unit 3 is arranged to be connected with the server 2 and used for displaying the position information of the vibration measurement modules 1, so that the vibration measurement modules 1 are monitored, and when the vibration measurement modules 1 have displacement, the display unit 3 can display the positions of the vibration measurement modules 1 in real time, so that the vibration measurement modules 1 can be tracked. The display unit 3 may be provided as a PC, a display screen, or the like.

Further, the system further comprises:

the input unit 4 is electrically connected with the server 2 and used for receiving a control instruction of an operator for the vibration measurement module 1 and generating a first external input signal corresponding to the vibration measurement module 1;

the server 2 is further configured to generate and send a corresponding control signal to the corresponding vibration measurement module 1 according to the first external input signal.

Specifically, still be provided with input unit 4 on server 2, input unit 4 can receive operating personnel to the control command of vibration measurement module 1 and generate the first external input signal that corresponds with this vibration measurement module 1 to transmit to server 2 on, server 2 generates and sends corresponding control signal to the module 1 that shakes that corresponds according to first external input signal, realizes the control to vibration measurement module 1. More specifically, a start timing signal may be sent to the control unit 14 by the server, so that the control unit 14 controls the timing units 16 to start timing and remotely modifies the preset timing interval corresponding to each timing unit 16, sends a sleep signal to the control unit 14, and causes the control unit 14 to control the alarm unit 19 to sleep, stop the alarm, and so on.

Further, the system further comprises:

the mobile terminal 5 is in communication connection with the server 2 and is used for displaying the position information of the vibration measuring module 1, receiving a control instruction of an operator for the vibration measuring module 1 and generating a second external input signal corresponding to the vibration measuring module 1;

the server 2 is further configured to generate and send a corresponding control signal to the corresponding vibration measurement module 1 according to the second external input signal.

Specifically, since the server 2 is located in a fixed monitoring room or the like and is inconvenient to move, a mobile terminal 5, such as a mobile phone, a tablet or the like, is provided in communication with the server 2. The mobile terminal 5 is convenient to carry, and the real-time position of the vibration measuring module 1 can be conveniently checked in the recovery vibration measuring module 1; in addition, the mobile terminal 5 can receive a control instruction of an operator for the vibration measurement module 1, generate a second external input signal corresponding to the vibration measurement module 1, and the server 2 generates and sends a corresponding control signal to the corresponding vibration measurement module 1 according to the second external input signal, so that the vibration measurement module 1 is controlled.

Although the embodiments of the present invention have been described in detail with reference to the accompanying drawings, the embodiments of the present invention are not limited to the details of the above embodiments, and various simple modifications can be made to the technical solutions of the embodiments of the present invention within the technical idea of the embodiments of the present invention, and the simple modifications all belong to the protection scope of the embodiments of the present invention.

It should be noted that the various features described in the above embodiments may be combined in any suitable manner without departing from the scope of the invention. In order to avoid unnecessary repetition, the embodiments of the present invention do not describe every possible combination.

Those skilled in the art will understand that all or part of the steps in the method according to the above embodiments may be implemented by a program, which is stored in a storage medium and includes several instructions to enable a single chip, a chip, or a processor (processor) to execute all or part of the steps in the method according to the embodiments of the present application. And the aforementioned storage medium includes: a U-disk, a removable hard disk, a Read-Only Memory (ROM), a Random Access Memory (RAM), a magnetic disk, or an optical disk, and various media capable of storing program codes.

In addition, any combination of various different implementation manners of the embodiments of the present invention can be made, and the embodiments of the present invention should also be regarded as the disclosure of the embodiments of the present invention as long as the combination does not depart from the spirit of the embodiments of the present invention.

Claims (10)

1. The utility model provides a module of testing vibration of oil surveying, the module of testing vibration (1) includes seismic acquisition unit (11), power supply unit (12) and memory cell (13), power supply unit (12) are used for supplying power for seismic acquisition unit (11) and memory cell (13), its characterized in that, the module of testing vibration (1) still includes:

a control unit (14), and a displacement detection unit (15), a timing unit (16), a positioning unit (17) and a communication unit (18) connected to the control unit (14);

the positioning unit (17) is used for acquiring the position of the vibration measurement module (1) in real time and generating position information;

the communication unit (18) is used for sending the position information to a server (2);

the displacement detection unit (15) is used for periodically detecting the displacement of the vibration measurement module (1) and generating a displacement signal;

the timing unit (16) is used for sending a wake-up signal to the control unit (14) according to a preset timing interval;

the control unit (14) is used for sending a starting signal to the positioning unit (17) and the communication unit (18) when the wake-up signal is received or when the vibration measuring module (1) is determined to have continuous displacement based on the received displacement signal.

2. The oil survey vibration measurement module according to claim 1, characterized in that the control unit (14) is an MCU.

3. The petroleum exploration vibration measurement module according to claim 1, characterized in that said displacement detection unit (15) is an acceleration sensor or a gyroscope.

4. The oil exploration vibration measurement module according to claim 1, characterized in that said oil exploration vibration measurement module (1) further comprises:

the alarm unit (19) is electrically connected with the control unit (14), and the control unit (14) is also used for sending an alarm signal to the alarm unit (19) while sending a starting signal to the positioning unit (17) and the communication unit (18).

5. The oil exploration vibration measurement module according to claim 4, characterized in that said alarm unit (19) is an audible and visual alarm.

6. The oil exploration vibration measurement module according to claim 4, characterized in that said power supply unit (12) is also used to supply power to a displacement detection unit (15), a timing unit (16), a positioning unit (17), a communication unit (18) and an alarm unit (19).

7. The oil survey vibration measurement module according to claim 1, characterized in that the communication unit (18) comprises: a Lora communication sub-unit (181) and a 4G communication sub-unit (182);

the control unit (14) is used for controlling the communication link to be switched between the Lora communication sub-unit (181) and the 4G communication sub-unit (182) according to the position of the vibration measurement module (1).

8. A monitoring system for a petroleum survey vibration measurement module, the system comprising:

a plurality of vibration measuring modules (1) according to any one of claims 1-7, spaced apart in a petroleum survey area;

the server (2) is in communication connection with each vibration measuring module (1);

and the display unit (3) is connected with the server (2) and is used for displaying the position information of the vibration measuring module (1).

9. The monitoring system of the petroleum survey vibration measurement module of claim 8, further comprising:

the input unit (4) is electrically connected with the server (2) and is used for receiving a control instruction of an operator for the vibration measurement module (1) and generating a first external input signal corresponding to the vibration measurement module (1);

the server (2) is also used for generating and sending a corresponding control signal to the corresponding vibration measuring module (1) according to the first external input signal.

10. The monitoring system of the petroleum survey vibration measurement module of claim 9, further comprising:

a mobile terminal (5) in communication connection with the server (2) and configured to:

displaying the position information of the vibration measuring module (1);

receiving a control instruction of an operator for the vibration measurement module (1), and generating a second external input signal corresponding to the vibration measurement module (1);

the server (2) is also used for generating and sending a corresponding control signal to the corresponding vibration measuring module (1) according to the second external input signal.

Images