CN118131304A - Intelligent calibration device for seismic exploration - Google Patents

Abstract

The invention relates to the technical field of seismic exploration, in particular to an intelligent calibration device for seismic exploration, which is used for solving the problem that the existing device cannot fundamentally solve impurities and particulate matters contained in paint; the intelligent calibration device for the seismic exploration comprises a tank body, wherein the tank body comprises an upper accommodating body and a lower accommodating body, and a filter screen is connected to the joint of the upper accommodating body and the lower accommodating body; the upper accommodating body and the lower accommodating body are respectively and rotatably connected with a stirring shaft, and the stirring shafts are connected with stirring rods; paint filling is in jar internal, and jar internal paint is placed for a long time after, rotates through control (mixing) shaft and can make the puddler stir the internal paint of jar for avoid layering after the paint of placing for a long time obtains stirring, treats the position exchange that the jar body made last accommodation body and lower accommodation body through the upset jar body after the paint stirring, thereby jar internal paint can filter through the filter screen, makes the impurity that contains in the paint obtain the separation, guarantees the normal use of paint, thereby guarantees the demarcation effect.

Description

Intelligent calibration device for seismic exploration

Technical Field

The invention relates to the technical field of seismic exploration, in particular to an intelligent calibration device for seismic exploration.

Background

In seismic exploration, the marks of the wave detection points and the shot points are of great significance, and firstly, the wave detection points and the shot points are respectively used for recording the propagation condition of the seismic wave. The wave detection point is arranged on the ground surface or a wellhead and is used for receiving the seismic wave signals and recording the arrival time and amplitude of the seismic waves. The shot point is a place where the seismic source is arranged, and the seismic waves are generated by triggering the seismic source. A plurality of geophones are usually placed on a straight line to record the arrival time and amplitude of seismic waves in different directions, which is helpful for analyzing the subsurface geologic structure, and secondly, the position and shape of the subsurface reflection interface can be more accurately determined through the spatial position correction of the geophones and the shot points. According to geological data or seismic profiles, equations of subsurface reflection interfaces can be established, and then propagation paths of seismic waves from a seismic source to receiving points on the ground are deduced by using basic principles of geometric seismology. Through space correction, the positions of the excitation point and the receiving point can be corrected to the positions of the incidence point and the emergent point of the seismic wave on the reference plane, so that errors caused by factors such as topography fluctuation, offset point height difference and the like are eliminated.

Paint can be applied as a widely used coating for the marking of spots and shots, but it often suffers from a number of problems during storage and use. During long-term storage of the paint, pigments and fillers in the paint may gradually settle due to gravity, resulting in delamination of the paint. The layering phenomenon not only affects the quality and stability of the paint, but also can cause problems of nozzle blockage, uneven painting and the like during use.

In order to solve the problem, the conventional intelligent calibration device for seismic exploration generally adopts a stirring mode, so that paint is kept in a uniformly mixed state in a tank body. However, this approach, while temporarily alleviating the problem of paint delamination, does not fundamentally address the impurities and particulates contained within the paint. These impurities and particulates can clog the nozzles during paint use, affecting the painting effect and even reducing the life of the paint.

Disclosure of Invention

The invention provides an intelligent calibration device for seismic exploration, which aims to solve the problem that impurities and particles contained in paint are not easy to solve when the existing device is marked by paint.

In order to alleviate the technical problems, the technical scheme provided by the invention is as follows:

The intelligent calibration device for the seismic exploration comprises a tank body, wherein the tank body comprises an upper accommodating body and a lower accommodating body, the upper accommodating body is connected with the lower accommodating body through a flange, and a filter screen is connected to the joint of the upper accommodating body and the lower accommodating body;

The upper accommodating body and the lower accommodating body are respectively and rotatably connected with a stirring shaft, and the stirring shafts are connected with stirring rods;

The stirring rod can stir paint in the tank body when rotating, the tank body is turned over so that the filter screen can filter paint in the tank body after the upper accommodating body and the lower accommodating body are in exchange positions.

Still further, all be connected with the discharge mouth on the upper accommodation body with the lower accommodation body, be provided with the discharge valve on the discharge mouth, install on the jar body and be used for controlling the automated processor of discharge valve.

Still further, the stirring rod stirring device comprises a stirring rod, and is characterized by further comprising a moving mechanism, wherein the moving mechanism comprises a mounting plate, the bottom of the mounting plate is rotationally connected with a first rotating shaft and a second rotating shaft, the first rotating shaft is in transmission connection with the stirring rod, two ends of the second rotating shaft are respectively connected with a moving wheel and a first bevel gear, and a second bevel gear meshed with the first bevel gear is connected to the first rotating shaft;

The first rotating shaft can be driven to rotate when the moving wheel rotates, and the stirring shaft can be driven to rotate when the first rotating shaft rotates.

Further, the upper accommodating body and the lower accommodating body are connected with magnetic couplers, and the magnetic couplers are connected with transmission rods;

the end part of the first rotating shaft is connected with a third bevel gear, and the transmission rod is connected with a fourth bevel gear matched with the third bevel gear.

Still further still include coupling mechanism, coupling mechanism includes the link, be connected with the staple bolt on the link, the jar body pass through the staple bolt connect in the link.

Still further, the moving mechanism further includes a riser connected to an upper surface of the mounting plate;

the connecting frame is connected with a rotating rod, and the rotating rod rotates on the vertical plate.

Further, a turnover mechanism for turning over the tank body is arranged on the mounting plate;

the turnover mechanism comprises a third rotating shaft which rotates on the mounting plate;

The third rotating shaft and the first rotating shaft are respectively connected with a first transmission tooth and a second transmission tooth which are meshed with each other;

the top of the third rotating shaft is connected with a third transmission tooth, and the end part of the rotating rod is connected with a fourth transmission tooth;

When the fourth transmission gear is meshed with the third transmission gear, the third rotating shaft can drive the connecting frame to rotate so that the tank body can be overturned.

Further, the third transmission gear is connected to the upper part of the third rotating shaft in a sliding manner through a key, the vertical plate is connected with an air cylinder, the output end of the air cylinder is connected with a rotating frame, and the rotating frame is connected to the third transmission gear in a rotating manner;

The cylinder can drive the third transmission gear to slide on the third rotating shaft when in operation so that the third transmission gear can be meshed with the fourth transmission gear.

Further, a positioning mechanism for positioning the connecting frame is arranged on the vertical plate;

The positioning mechanism comprises a positioning frame connected to the upper part of the vertical plate, a sliding rod is connected to the positioning frame in a sliding manner, a positioning strip is connected to the bottom of the sliding rod, and a spring is connected between the positioning strip and the positioning frame;

The positioning strips can be extruded on the connecting frame so that the tank body on the connecting frame is in a vertical state.

Further, a distance measuring mechanism is arranged on the mounting plate;

The distance measuring mechanism comprises a mounting seat, a storage shaft is connected to the mounting seat, a tape is wound on the storage shaft, a balancing weight is connected to the end portion of the tape, and a containing groove for placing the balancing weight is formed in the mounting plate.

The beneficial effects of the invention are analyzed as follows:

the intelligent calibration device for the seismic exploration comprises a tank body, wherein the tank body comprises an upper accommodating body and a lower accommodating body, the upper accommodating body and the lower accommodating body are connected through a flange, and a filter screen is connected to the joint of the upper accommodating body and the lower accommodating body; the upper accommodating body and the lower accommodating body are respectively and rotatably connected with a stirring shaft, and the stirring shafts are connected with stirring rods; the paint in the tank body can be stirred when the stirring rod rotates, and the tank body can be turned over so that the filter screen can filter the paint in the tank body after the upper accommodating body and the lower accommodating body are in exchange positions.

Paint filling is in the jar internal, accessible flange dismouting between the last accommodation body of jar body and the lower accommodation body during the use, unpack apart the back between going up the accommodation body and the lower accommodation body and can wash the inside of jar body and filter screen, can be with paint filling in last accommodation body or lower accommodation body after waiting to wash, the internal paint of jar is placed for a long time after, can make the puddler stir the internal paint of jar through controlling the (mixing) shaft rotation for the paint of placing for a long time is avoided layering after obtaining the stirring, make the position exchange of going up the accommodation body and the lower accommodation body through the upset jar body after the paint stirring, thereby the internal paint of jar can be filtered through the filter screen, make the impurity that contains in the paint obtain separating, guarantee the normal use of paint, thereby guarantee the demarcation effect.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the related art, the drawings that are required to be used in the description of the embodiments or the related art will be briefly described, and it is apparent that the drawings in the description below are some embodiments of the present invention, and other drawings may be obtained according to the drawings without inventive effort for those skilled in the art.

FIG. 1 is a schematic diagram of the overall structure of the present invention;

FIG. 2 is a schematic diagram of the whole structure of the present invention;

FIG. 3 is a schematic view of the structure of the tank of the present invention;

FIG. 4 is a schematic view of the structure of the first shaft of the present invention;

FIG. 5 is a schematic view of a moving mechanism according to the present invention;

FIG. 6 is a schematic diagram of the turnover mechanism of the present invention;

Fig. 7 is a schematic view of the structure of the turret according to the present invention.

Icon:

100. A tank body; 110. an upper housing body; 120. a lower accommodating body; 130. a stirring shaft; 140. a stirring rod; 150. a magnetic coupler; 160. a transmission rod; 170. a fourth bevel gear; 180. a discharge nozzle; 190. a discharge valve; 200. a connecting mechanism; 210. a connecting frame; 220. a rotating rod; 230. a fourth drive tooth; 240. a hoop; 250. a filter screen; 300. a moving mechanism; 310. a mounting plate; 320. a push rod; 321. a grip; 330. a riser; 340. a first rotating shaft; 341. a second bevel gear; 350. a second rotating shaft; 351. a first bevel gear; 352. a moving wheel; 360. a third bevel gear; 400. a positioning mechanism; 410. a positioning frame; 420. a positioning strip; 430. a slide bar; 440. a spring; 500. a turnover mechanism; 510. a third rotating shaft; 520. a first drive tooth; 530. a second drive tooth; 540. a third drive tooth; 550. a cylinder; 551. a control lever; 560. a rotating frame; 600. a distance measuring mechanism; 610. a mounting base; 620. a storage shaft; 630. balancing weight; 640. an accommodating groove.

Detailed Description

The following description of the embodiments of the present invention will be made apparent and fully in view of the accompanying drawings, in which some, but not all embodiments of the invention are shown. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

In the description of the present invention, it should be noted that the directions or positional relationships indicated by the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc. are based on the directions or positional relationships shown in the drawings, are merely for convenience of describing the present invention and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present invention will be understood in specific cases by those of ordinary skill in the art.

Example 1

1-7, An intelligent calibration device for seismic exploration comprises a tank body 100, wherein the tank body 100 comprises an upper accommodating body 110 and a lower accommodating body 120, the upper accommodating body 110 and the lower accommodating body 120 are connected through a flange, and a filter screen 250 is connected at the joint of the upper accommodating body 110 and the lower accommodating body 120; the upper accommodating body 110 and the lower accommodating body 120 are respectively and rotatably connected with a stirring shaft 130, and the stirring shaft 130 is connected with a stirring rod 140; the paint in the can 100 can be stirred when the stirring rod 140 rotates, and the filter screen 250 can filter the paint in the can 100 after the can 100 is turned over so that the upper and lower containers 110 and 120 exchange positions.

The working mechanism of the intelligent calibration device for seismic exploration is as follows:

Paint filling is in jar body 100, the accessible flange dismouting between the last accommodation body 110 of jar body 100 and the lower accommodation body 120 during the use, unpack and tear open between last accommodation body 110 and the lower accommodation body 120 the back and can wash the inside of jar body 100 and filter screen 250, can pack paint in last accommodation body 110 or lower accommodation body 120 after waiting to wash, after placing for a long time the paint in jar body 100, can make puddler 140 stir the paint in the jar body 100 through controlling puddler 130 rotation, make the paint of placing for a long time avoid layering after obtaining stirring, make the position exchange of last accommodation body 110 and lower accommodation body 120 through upset jar body 100 after the paint stirring, thereby paint in jar body 100 can be filtered through filter screen 250, make the impurity that paint contained obtain separating, guarantee the normal use of paint, thereby guarantee the demarcation effect.

With respect to how the paint within the can 100 is discharged, in particular:

the upper and lower receiving bodies 110 and 120 are connected with a discharge nozzle 180, a discharge valve 190 is provided on the discharge nozzle 180, and an automated processor for controlling the discharge valve 190 is mounted on the tank 100.

The upper and lower receiving bodies 110 and 120 are provided with the discharge nozzles 180, and the discharge valve 190 on the upper or lower receiving body 110 or 120 at the lower part is controlled to be opened according to the positions of the upper and lower receiving bodies 110 and 120, so that paint in the can body 100 is discharged through the discharge nozzles 180;

The drain valve 190 opens based on feedback from an automated processor that includes, a data acquisition module: is responsible for receiving the seismic signals from the geophones and converting them into digital signals for further processing; and a signal processing module: the method is responsible for preprocessing the acquired seismic signals, including filtering, denoising, enhancing and other operations, so as to improve the signal quality and the readability; event detection module: the method is responsible for automatically detecting the seismic event, namely the time point when the seismic wave reaches the detector; waveform classification and identification module: is responsible for classifying and identifying the seismic waveforms to determine different types of seismic events or formation characteristics; data storage and management module: is responsible for storing the processed seismic data and providing data management and query functions;

when the automated processor determines a seismic event or an underlying feature, the vent valve 190 is opened.

Regarding the structure of the moving mechanism 300, specifically:

The device comprises a moving mechanism 300, wherein the moving mechanism 300 comprises a mounting plate 310, a first rotating shaft 340 and a second rotating shaft 350 are rotatably connected to the bottom of the mounting plate 310, the first rotating shaft 340 is in transmission connection with a stirring rod 140, two ends of the second rotating shaft 350 are respectively connected with a moving wheel 352 and a first bevel gear 351, and a second bevel gear 341 meshed with the first bevel gear 351 is connected to the first rotating shaft 340; the moving wheel 352 can drive the first rotating shaft 340 to rotate when rotating, and the stirring shaft 130 can be driven to rotate when the first rotating shaft 340 rotates.

When the moving mechanism 300 moves, the moving wheel 352 rolls on the ground, so that the second rotating shaft 350 rotates, and at the moment, the first bevel gear 351 connected with the second rotating shaft 350 rotates, so that the first bevel gear 351 drives the second bevel gear 341 to rotate, and then the first rotating shaft 340 rotates, and the rotating first rotating shaft 340 drives the stirring shaft 130 to rotate, so that paint in the tank 100 can be stirred and uniformly mixed in the moving process of the mounting plate 310.

In the alternative of this embodiment, it is preferable that:

The upper accommodating body 110 and the lower accommodating body 120 are connected with a magnetic coupler 150, and the magnetic coupler 150 is connected with a transmission rod 160; the end of the first shaft 340 is connected with a third bevel gear 360, and the driving rod 160 is connected with a fourth bevel gear 170 matched with the third bevel gear 360.

The magnetic coupler 150 is arranged to enable the tank body 100 to maintain tightness, the transmission rod 160 can rotate to drive the stirring shaft 130 to rotate through the magnetic coupler 150, the third bevel gear 360 synchronously rotates when the first rotating shaft 340 rotates, the fourth bevel gear 170 meshed with the third bevel gear 360 can be synchronously rotated when the third bevel gear 360 rotates, and the transmission rod 160 connected with the fourth bevel gear 170 further rotates, so that the stirring rod 140 stirs paint in the tank body 100.

Regarding the structure of the connection mechanism 200, specifically:

The tank body 100 is connected to the connecting frame 210 through the anchor ear 240.

The tank body 100 is mounted on the device through the anchor ear 240, when the tank body 100 is mounted, the fourth bevel gear 170 at the lowest part can be meshed with the third bevel gear 360 when the tank body 100 is in a vertical state, at the moment, the middle position of the tank body 100 corresponds to the middle position of the connecting frame 210, and therefore the fourth bevel gear 170 at the upper part can still be meshed with the third bevel gear 360 after moving to the lower part after the tank body 100 is overturned.

In the alternative of this embodiment, it is preferable that:

the moving mechanism 300 further includes a riser 330, the riser 330 being attached to the upper surface of the mounting plate 310; the connection frame 210 is connected with a rotating rod 220, and the rotating rod 220 rotates on a vertical plate 330.

The vertical plate 330 is arranged to enable the connecting frame 210 to be installed, and when the rotating rod 220 rotates, the connecting frame 210 can drive the tank body 100 to turn over.

Regarding the structure of the tilting mechanism 500, specifically:

The mounting plate 310 is provided with a turnover mechanism 500 for turning over the can 100; the turnover mechanism 500 includes a third rotating shaft 510, and the third rotating shaft 510 rotates on the mounting plate 310; the third rotating shaft 510 and the first rotating shaft 340 are respectively connected with a first transmission tooth 520 and a second transmission tooth 530 which are meshed with each other; the top of the third rotating shaft 510 is connected with a third transmission tooth 540, and the end part of the rotating rod 220 is connected with a fourth transmission tooth 230; when the fourth gear 230 is engaged with the third gear 540, the third rotating shaft 510 may drive the connecting frame 210 to rotate so that the can 100 is turned over.

The mounting plate 310 is further connected with a push rod 320, the push rod 320 is provided with a handle 321, the mounting plate 310 can be pushed to move by the handle 321, when the mounting plate 310 moves, the first rotating shaft 340 is in a rotating state, at the moment, the second transmission gear 530 on the first rotating shaft 340 can drive the first transmission gear 520 to rotate, so that the third rotating shaft 510 rotates, at the moment, the third transmission gear 540 on the third rotating shaft 510 rotates, and when the third transmission gear 540 is meshed with the fourth transmission gear 230, the fourth transmission gear 230 is driven to rotate, at the moment, the rotating rod 220 rotates, and the can 100 is turned.

In the alternative of this embodiment, it is preferable that:

The third transmission gear 540 is slidably connected to the upper part of the third rotating shaft 510 through a key, the vertical plate 330 is connected with a cylinder 550, the output end of the cylinder 550 is connected with a rotating frame 560, and the rotating frame 560 is rotatably connected to the third transmission gear 540; the cylinder 550 is operable to drive the third gear 540 to slide on the third shaft 510 such that the third gear 540 is engaged with the fourth gear 230.

The third driving gear 540 can slide axially relative to the third rotating shaft 510 and rotate synchronously along with the third rotating shaft 510, the output end of the air cylinder 550 is connected with the third driving gear 540 through a rotating frame 560, so that the rotation of the third driving gear 540 is not interfered, the shrinkage of the air cylinder 550 can drive the third driving gear 540 to lift, thereby controlling the meshing state of the third driving gear 540 and the fourth driving gear 230, a control rod 551 is arranged on the push rod 320, the control rod 551 can rotate relative to the push rod 320, the air cylinder 550 can be started by manually controlling the swing of the control rod 551, and the air cylinder 550 can be controlled in an electric control and pneumatic control manner by the control rod 551, and the specific principle is the prior art and is not repeated herein;

As for the timing control for controlling the overturning of the can 100, specifically, the fluidity of the paint in the can 100 is deteriorated after the paint is placed for a long time, so that the rotation resistance of the stirring shaft 130 is high in the initial stage, the resistance for pushing the mounting plate 310 to move is high at this time, and the rotation resistance of the stirring shaft 130 is reduced after the paint in the can 100 is uniformly stirred, so that the movement resistance of the mounting plate 310 is reduced, at this time, the extension of the cylinder 550 can be controlled to overturn the can 100, and then the paint in the can 100 can be used.

Regarding the structure of the positioning mechanism 400, specifically:

The riser 330 is provided with a positioning mechanism 400 for positioning the connection frame 210; the positioning mechanism 400 comprises a positioning frame 410 connected to the upper part of the vertical plate 330, a sliding rod 430 is connected to the positioning frame 410 in a sliding manner, a positioning strip 420 is connected to the bottom of the sliding rod 430, and a spring 440 is connected between the positioning strip 420 and the positioning frame 410; the positioning strip 420 may be pressed against the connection frame 210 such that the can body 100 on the connection frame 210 is in a vertical state.

When the connecting frame 210 is not rotated by the driving force, the positioning strip 420 moves down under the action of the elastic force of the spring 440 and is attached to one side surface of the connecting frame 210, so that the position of the connecting frame 210 is fixed, the vertical state of the tank body 100 is ensured, the connecting frame 210 can push the positioning strip 420 to move upwards after being rotated by the driving force, and the tank body 100 is in the vertical state after the positioning strip 420 moves upwards, at the moment, the driving force on the connecting frame 210 is released, and the connecting frame 210 is positioned again.

Regarding the structure of ranging mechanism 600, specifically:

The mounting plate 310 is provided with a ranging mechanism 600; the ranging mechanism 600 comprises a mounting seat 610, a storage shaft 620 is connected to the mounting seat 610, a tape is wound on the storage shaft 620, a balancing weight 630 is connected to the end of the tape, and a containing groove 640 for placing the balancing weight 630 is formed in the mounting plate 310.

During the seismic exploration construction, place balancing weight 630 on ground, the weight of balancing weight 630 pulls the tape to mounting panel 310 removes the back tape and is released, then can know the position interval of marks such as spouting shot and geophone and fixed point according to the distance that shows on the tape, rotates behind the use and accomodates axle 620 and rolls up the tape, and places balancing weight 630 in holding tank 640.

Finally, it should be noted that: the above embodiments are only for illustrating the technical solution of the present invention, and are not limited thereto; although the invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some or all of the technical features can be replaced with equivalents; such modifications and substitutions do not depart from the essence of the corresponding technical solutions from the scope of the technical solutions of the embodiments of the present invention.

Claims (10)

1. An intelligent calibration device for seismic exploration is characterized in that;

The novel water tank comprises a tank body (100), wherein the tank body (100) comprises an upper accommodating body (110) and a lower accommodating body (120), the upper accommodating body (110) and the lower accommodating body (120) are connected through a flange, and a filter screen (250) is connected to the joint of the upper accommodating body (110) and the lower accommodating body (120);

Stirring shafts (130) are rotatably connected in the upper accommodating body (110) and the lower accommodating body (120), and stirring rods (140) are connected to the stirring shafts (130);

the stirring rod (140) can stir paint in the tank body (100) when rotating, and the tank body (100) can be turned over so that the filter screen (250) can filter paint in the tank body (100) after the upper accommodating body (110) and the lower accommodating body (120) are in exchange positions.

2. The intelligent calibration device for seismic exploration according to claim 1, wherein;

the automatic tank is characterized in that the upper accommodating body (110) and the lower accommodating body (120) are both connected with a discharge nozzle (180), a discharge valve (190) is arranged on the discharge nozzle (180), and an automatic processor for controlling the discharge valve (190) is arranged on the tank body (100).

3. The intelligent calibration device for seismic exploration according to claim 2, wherein;

The stirring device comprises a stirring rod (140), and is characterized by further comprising a moving mechanism (300), wherein the moving mechanism (300) comprises a mounting plate (310), a first rotating shaft (340) and a second rotating shaft (350) are rotatably connected to the bottom of the mounting plate (310), the first rotating shaft (340) is in transmission connection with the stirring rod (140), two ends of the second rotating shaft (350) are respectively connected with a moving wheel (352) and a first bevel gear (351), and a second bevel gear (341) meshed with the first bevel gear (351) is connected to the first rotating shaft (340);

The first rotating shaft (340) can be driven to rotate when the moving wheel (352) rotates, and the stirring shaft (130) can be driven to rotate when the first rotating shaft (340) rotates.

4. The intelligent calibration device for seismic exploration according to claim 3, wherein;

The upper accommodating body (110) and the lower accommodating body (120) are connected with a magnetic coupler (150), and the magnetic coupler (150) is connected with a transmission rod (160);

The end part of the first rotating shaft (340) is connected with a third bevel gear (360), and the transmission rod (160) is connected with a fourth bevel gear (170) matched with the third bevel gear (360).

5. The intelligent calibration device for seismic exploration according to claim 4, wherein;

still include coupling mechanism (200), coupling mechanism (200) include link (210), be connected with staple bolt (240) on link (210), jar body (100) pass through staple bolt (240) connect in link (210).

6. The intelligent calibration device for seismic exploration according to claim 5, wherein;

the moving mechanism (300) further comprises a riser (330), the riser (330) being connected to the upper surface of the mounting plate (310);

The connecting frame (210) is connected with a rotating rod (220), and the rotating rod (220) rotates on the vertical plate (330).

7. The intelligent calibration device for seismic exploration according to claim 6, wherein;

The mounting plate (310) is provided with a turnover mechanism (500) for turning over the tank body (100);

The turnover mechanism (500) comprises a third rotating shaft (510), and the third rotating shaft (510) rotates on the mounting plate (310);

the third rotating shaft (510) and the first rotating shaft (340) are respectively connected with a first transmission tooth (520) and a second transmission tooth (530) which are meshed with each other;

The top of the third rotating shaft (510) is connected with a third transmission tooth (540), and the end part of the rotating rod (220) is connected with a fourth transmission tooth (230);

When the fourth transmission gear (230) is meshed with the third transmission gear (540), the third rotating shaft (510) can drive the connecting frame (210) to rotate so as to enable the tank body (100) to turn over.

8. The intelligent calibration device for seismic exploration according to claim 7, wherein;

The third transmission gear (540) is connected to the upper part of the third rotating shaft (510) in a sliding way through a key, the vertical plate (330) is connected with an air cylinder (550), the output end of the air cylinder (550) is connected with a rotating frame (560), and the rotating frame (560) is rotationally connected to the third transmission gear (540);

The cylinder (550) is operable to drive the third gear (540) to slide on the third shaft (510) such that the third gear (540) is engageable with the fourth gear (230).

9. The intelligent calibration device for seismic exploration according to claim 8, wherein;

a positioning mechanism (400) for positioning the connecting frame (210) is arranged on the vertical plate (330);

The positioning mechanism (400) comprises a positioning frame (410) connected to the upper portion of the vertical plate (330), a sliding rod (430) is connected to the positioning frame (410) in a sliding mode, a positioning strip (420) is connected to the bottom of the sliding rod (430), and a spring (440) is connected between the positioning strip (420) and the positioning frame (410);

the positioning strip (420) can be extruded on the connecting frame (210) so that the tank body (100) on the connecting frame (210) is in a vertical state.

10. The intelligent calibration device for seismic exploration according to claim 9, wherein;

a ranging mechanism (600) is arranged on the mounting plate (310);

The ranging mechanism (600) comprises a mounting seat (610), a storage shaft (620) is connected to the mounting seat (610), a tape is wound on the storage shaft (620), a balancing weight (630) is connected to the end portion of the tape, and a containing groove (640) for placing the balancing weight (630) is formed in the mounting plate (310).