CN214586060U - Geophysical exploration system based on Internet of things - Google Patents

Abstract

The utility model relates to the technical field of geological exploration, in particular to a geophysical exploration system based on the Internet of things, which comprises a protective box, a detection body and a detector, wherein a signal processor, a signal receiving module and an Internet of things connecting module are arranged in the detection body, the signal processor is respectively connected with the signal receiving module and the Internet of things connecting module through transmission lines, a signal transmission module, a positioning module and a detection module are arranged in the detector, the signal transmission module is respectively connected with the positioning module and the detection module through conducting wires, a protective cavity is arranged in the protective box, and through the arrangement of the detector and the detection body, an operator carries the detector while working in a mode of continuous repetition and full coverage of a mining area, thereby sending a detection result to the detection body by utilizing the mobile internet and a big data application technology under the condition of not affecting normal working, thereby completing the geophysical exploration work for the area.

Description

Geophysical exploration system based on Internet of things

Technical Field

The utility model relates to a geological exploration technical field specifically is a geophysical prospecting system based on thing networking.

Background

Geophysical prospecting is an important means of geological work, according to the physical property difference of geologic body, through the data acquisition of the different positions of earth's surface, realize the prospecting purpose of geology and mineral products, and the conventional art is that special instrument carries out the survey, needs professional operation use to because need carry a large amount of equipment in the prospecting process to go up a mountain, its data acquisition has a large amount of limitations. Meanwhile, the existing exploration equipment is not provided with protective equipment, and is easy to collide and damage in the using process, so that an exploration system with a detection device and a processing device separated is needed, geological personnel only need to carry a detector to work in a mode of continuous repetition and area full coverage in a mining area, and meanwhile, the mobile internet and a big data application technology are utilized to carry out geophysical characteristic exploration, and exploration in the area is realized.

SUMMERY OF THE UTILITY MODEL

Technical problem to be solved

Not enough to prior art, the utility model provides a geophysical prospecting system based on thing networking.

(II) technical scheme

In order to achieve the above object, the utility model provides a following technical scheme: a geophysical exploration system based on the Internet of things comprises a protective box, a detection body and a detector, wherein a signal processor, a signal receiving module and an Internet of things connection module are arranged in the detection body, the signal processor is respectively connected with the signal receiving module and the Internet of things connection module through transmission lines, a signal transmission module, a positioning module and a detection module are arranged in the detector, the signal transmission module is respectively connected with the positioning module and the detection module through wires, a protective cavity is arranged in the protective box, a protective plate is hinged to the top end of the side wall on the right side of the protective cavity, a protective plate is arranged in the protective cavity in a sliding mode, the top end of the protective plate is provided with the detection body, a sliding groove is arranged at the bottom end of the protective plate, sliding blocks are arranged on the left side and the right side of the sliding groove in a sliding mode, supporting rods are hinged to the left side and the right side of the bottom end of the protective cavity, the top ends of the supporting rods are respectively hinged to the bottom ends of the sliding blocks, the protective cavity bottom rotates and sets up the hob, the protective housing is located the protective cavity bottom and sets up driving motor, the driving motor output is connected with the hob, the protective cavity is located the hob left and right sides and rotates respectively and sets up drive gear, drive gear meshes with the hob mutually, the drive gear lateral wall sets up the actuating lever, the articulated conduction pole between drive gear one end and the bracing piece is kept away from to the actuating lever.

In order to facilitate storing the detection result to make things convenient for the audit and the inspection of later stage data, the utility model discloses the improvement has, survey this internal memory that sets up, the memory passes through the transmission line with signal processor and is connected.

In order to carry out the omnidirectional to the convenience and survey geophysical, the utility model discloses the improvement has, the detection module includes gravity detection device and magnetic detection device.

In order to facilitate the heat dispersion of the body of surveying of promotion, the utility model discloses the improvement has, the protective cavity lateral wall sets up the louvre.

In order to facilitate the prevention of dust impurity among the external environment from being infected with and surveying the body surface to the use of body is surveyed in the influence, the utility model discloses the improvement has, set up the filter screen in the louvre.

In order to facilitate the removal of control detection body, the utility model discloses the improvement has, the protective housing bottom sets up the universal wheel.

(III) advantageous effects

Compared with the prior art, the utility model provides a geophysical prospecting system based on thing networking possesses following beneficial effect:

this geophysical prospecting system based on thing networking through the setting of detector and detection body, operating personnel carries the detector in the continuous repeated mode work with regional full coverage in mining area to utilize mobile internet and big data application technique to send the result of surveying to the detection body under the condition that does not influence normal work, thereby accomplish the geophysical prospecting work to this region. Through the arrangement of the protective box, the screw rod, the driving gear and the supporting rod. The body is surveyed in the control of being convenient for carries out altitude mixture control to be convenient for deposit the detection body, promote the barrier propterty of surveying the body simultaneously, prevent to collide with, simultaneously when the received signal is not good, can work through control driving motor, thereby the drive is surveyed the body and is carried out the regulation of height, thereby is convenient for accept the signal of detector transmission, thereby is convenient for promote signal reception quality.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic structural view of the protection box of the present invention in a closed state;

FIG. 3 is a schematic structural view of the probe body of the present invention in a working state;

in the figure: 1. a protective box; 2. detecting a body; 3. a detector; 4. a signal processor; 5. a signal receiving module; 6. the Internet of things connection module; 7. a signal transmission module; 8. a positioning module; 9. a detection module; 10. a protective cavity; 11. a protective cover; 12. a protection plate; 13. a chute; 14. a slider; 15. a support bar; 16. a screw rod; 17. a drive motor; 18. a drive gear; 19. a drive rod; 20. a conductive rod; 21. a memory; 22. a gravity detection device; 23. a magnetic force detecting device; 24. heat dissipation holes; 25. a universal wheel.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-3, a geophysical exploration system based on the internet of things comprises a protective box 1, a detection body 2 and a detector 3, wherein a signal processor 4, a signal receiving module 5 and an internet of things connection module 6 are arranged in the detection body 2, the signal processor 4 is respectively connected with the signal receiving module 5 and the internet of things connection module 6 through transmission lines, a signal transmission module 7, a positioning module 8 and a detection module 9 are arranged in the detector 3, the signal transmission module 7 is respectively connected with the positioning module 8 and the detection module 9 through conducting wires, a protective cavity 10 is arranged in the protective box 1, a protective cover 11 is hinged to the top end of the right side wall of the protective cavity 10, a protective plate 12 is arranged in the protective cavity 10 in a sliding manner, the detection body 2 is arranged at the top end of the protective plate 12, a sliding chute 13 is arranged at the bottom end of the protective plate 12, the sliding of 13 left and right sides of spout sets up slider 14, the articulated bracing piece 15 of 10 bottom left and right sides of protection cavity, 15 tops of bracing piece are articulated with 14 bottoms of slider respectively, 10 bottoms of protection cavity rotate and set up hob 16, protection box 1 is located 10 bottoms of protection cavity and sets up driving motor 17, driving motor 17 output is connected with hob 16, protection cavity 10 is located 16 left and right sides of hob and rotates respectively and set up drive gear 18, drive gear 18 meshes with hob 16 mutually, the drive gear 18 lateral wall sets up actuating lever 19, actuating lever 19 keeps away from articulated conduction pole 20 between drive gear 18 one end and the bracing piece 15.

The memory 21 is arranged in the detection body 2, and the memory 21 is connected with the signal processor 4 through a transmission line, so that detection results can be conveniently stored, and later-period data examination and check can be conveniently carried out.

The detection module 9 comprises a gravity detection device 22 and a magnetic detection device 23, and facilitates omnibearing detection of geophysical.

The side wall of the protective cavity 10 is provided with the heat dissipation holes 24, so that the heat dissipation performance of the detection body 2 is improved.

Set up the filter screen in the louvre 24, be convenient for prevent that the dust impurity among the external environment from being infected with on surveying body 2 surface to the use of body 2 is surveyed in the influence.

The universal wheel 25 is arranged at the bottom end of the protective box 1, so that the detection body 2 can be controlled to move conveniently.

The gravity detecting device 22 is an instrument for measuring the gravity acceleration or the change rate of the gravity acceleration along with the change of the place in the gravity exploration, and the gravity detecting device 22 adopts a portable CG-6 relative gravimeter.

The magnetic force detecting device 23 is an instrument that measures the intensity and direction of the magnetic field. Magnetometers for measuring the intensity of the geomagnetic field can be classified into absolute magnetometers and relative magnetometers. The device is mainly used for collecting magnetic anomaly data and measuring rock magnetic parameters, and the magnetic detection device 23 adopts an ACZ-8 type proton magnetometer.

The signal transmission module 7 and the signal receiving module 5 conduct data by using wireless technology. The signal transmission module 7 is used for generating sinusoidal signals with the frequency of 20 Hz-200 kHz. In addition to having a voltage output, there is also a power output. The signal receiving module 5 mainly receives the signal, converts the signal into information in the same physical form as that of the signal, and transmits the information to the signal sink, so that the decoding process is completed.

To sum up, in the geophysical prospecting system based on the internet of things, when in use, an operator carries the detector 3 while working in a mine area in a continuous repeated and area full-coverage mode, the detection module 9 of the detector 3 detects the gravity and magnetic force of the location, then the position information of the positioning module 8 is transmitted to the detection body 2 through the signal transmission module 7, meanwhile, the operator opens the protective cover 11, then the operator controls the driving motor 17 to work, so as to drive the screw rod 16 to rotate, so as to drive the driving gear 18 and the driving rod 19 to rotate, so as to drive the supporting rod 15 to perform angular offset through the conducting rod 20, so as to drive the detection body 2 to move upwards, so that the detection body 2 can receive signals transmitted by the detector 3 through the signal receiving module 5, and then transmit the received signals to the signal processor 4 to process the signals, and then, the processed signals are transmitted to the Internet of things through the Internet of things connection module 6, so that the geological condition of the area is detected.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides a geophysical prospecting system based on thing networking, includes guard box (1), surveys body (2) and detector (3), its characterized in that: the detection device is characterized in that a signal processor (4), a signal receiving module (5) and an internet of things connecting module (6) are arranged in the detection body (2), the signal processor (4) is respectively connected with the signal receiving module (5) and the internet of things connecting module (6) through transmission lines, a signal transmission module (7), a positioning module (8) and a detection module (9) are arranged in the detector (3), the signal transmission module (7) is respectively connected with the positioning module (8) and the detection module (9) through leads, a protection cavity (10) is arranged in the protection box (1), a protection cover (11) is hinged to the top end of the side wall on the right side of the protection cavity (10), a protection plate (12) is arranged in the protection cavity (10) in a sliding mode, the detection body (2) is arranged at the top end of the protection plate (12), and a sliding chute (13) is arranged at the bottom end of the protection plate (12), the utility model discloses a safe and convenient guard box, including spout (13), protection cavity (10) bottom left and right sides, the articulated bracing piece (15) of protection cavity (10) bottom left and right sides, bracing piece (15) top is articulated with slider (14) bottom respectively, protection cavity (10) bottom is rotated and is set up hob (16), protection box (1) is located protection cavity (10) bottom and sets up driving motor (17), driving motor (17) output is connected with hob (16), protection cavity (10) are located hob (16) left and right sides and rotate respectively and set up drive gear (18), drive gear (18) mesh with hob (16), drive gear (18) lateral wall sets up actuating lever (19), articulated conduction pole (20) between drive gear (18) one end and bracing piece (15) are kept away from in actuating lever (19).

2. The internet of things-based geophysical survey system of claim 1, wherein: a memory (21) is arranged in the detection body (2), and the memory (21) is connected with the signal processor (4) through a transmission line.

3. The internet of things-based geophysical survey system of claim 1, wherein: the detection module (9) comprises a gravity detection device (22) and a magnetic detection device (23).

4. The internet of things-based geophysical survey system of claim 1, wherein: the side wall of the protection cavity (10) is provided with heat dissipation holes (24).

5. The internet of things-based geophysical survey system of claim 4, wherein: and a filter screen is arranged in the heat dissipation hole (24).

6. The internet of things-based geophysical survey system of claim 1, wherein: the bottom end of the protective box (1) is provided with universal wheels (25).

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