CN113109545A

CN113109545A - Geological survey big data acquisition and analysis equipment

Info

Publication number: CN113109545A
Application number: CN202110409992.3A
Authority: CN
Inventors: 尚忠莉
Original assignee: Laixi Xinhe Engineering Technical Service Center
Current assignee: Laixi Xinhe Engineering Technical Service Center
Priority date: 2021-04-16
Filing date: 2021-04-16
Publication date: 2021-07-13

Abstract

The invention provides geological survey big data acquisition and analysis equipment, which comprises a supporting device; the two groups of supporting devices are arranged, and the supporting devices are arranged in a rectangular structure; the two electric telescopic rods are arranged in total, and the two electric telescopic rods are fixedly arranged at the center of the top of the supporting plate in the supporting device; the mounting plates are fixedly mounted at the tops of the two electric telescopic rods and are arranged in a rectangular plate-shaped structure, and handles are fixedly mounted at the tops of the mounting plates in a bilateral symmetry manner; the protective device is arranged at the center of the top of the mounting plate, and the protective shell of the protective device is fixedly connected with the top of the mounting plate.

Description

Geological survey big data acquisition and analysis equipment

Technical Field

The invention belongs to the technical field of geological survey, and particularly relates to a geological survey big data acquisition and analysis device.

Background

The geological survey is to survey and detect geology by various means and methods, determine a proper bearing stratum, determine a foundation type according to the foundation bearing capacity of the bearing stratum, calculate the investigation and research activities of basic parameters, find an industrially significant mineral deposit in the mineral product general survey, provide mineral product reserves and geological data required by mine construction design for finding out the quality and quantity of the mineral product and the technical conditions of mining and utilization, and carry out investigation and research work on the geological conditions of rocks, stratums, structures, mineral products, hydrology, landforms and the like in a certain area.

If the application number is: in CN 201810631060.1's patent, a geological survey device is disclosed, relate to geological survey apparatus technical field, the power distribution box comprises a box body, the box passes through a damping pivot and rotates the connection case lid, inside sponge chamber, storing chamber and the sample chamber of being equipped with of box, the case lid passes through three rotations of damping pivot and connects the straight board, the equal fixed spring post in bottom half four corners, spring post lower extreme installation universal wheel. The invention not only can lead the surveying equipment to be stably placed in the complex environment in the field, but also can carry various geological surveying equipment, lead the geological surveying equipment not to be easy to lose or damage, simultaneously has various functions of vibration resistance, easy carrying, high height adjustment and the like, and is very suitable for geological surveying workers to carry out geological surveying work in the field.

Based on the above, the inventor finds that the current geological survey device generally only has the soil sampling function, and can not analyze the soil after the soil sampling is finished, so that after the sampling is finished, the analysis is carried back to the laboratory, which not only reduces the geological survey progress, but also changes the soil sample along with the change of time, which causes the inaccurate analysis data and inconvenient use, and the traditional geological survey device can not be firmly contacted with the ground when in use, when the drill bit drills into hard soil or rock, the drill bit is easy to be damaged, most of the existing geological surveying devices are manual sampling, and cannot sample the soil at different depths, so that the accuracy of data acquisition is influenced, and the existing geological survey device can not ensure that the sample is not polluted after the sampling is finished, so that the analysis result is influenced, and the existing geological survey device can not meet the current use requirement.

Disclosure of Invention

In order to solve the technical problems, the invention provides a geological survey big data acquisition and analysis device, which aims to solve the problems that the existing device only has a soil sampling function, can not analyze soil after soil sampling is finished, can not be firmly contacted with the ground, can not easily damage a drill bit when the drill bit drills into hard soil or rock, can not sample soil at different depths, and can not ensure that the sample is not polluted after sampling is finished.

The purpose and the effect of the geological survey big data acquisition and analysis equipment are achieved by the following specific technical means:

a geological survey big data acquisition and analysis device comprises a supporting device, an electric telescopic rod, a mounting plate, a buzzer, a protective device, an anti-collision structure, an acquisition structure, a pressing block, a switch, an analyzer body and a sampling device; the two groups of supporting devices are arranged, and the supporting devices are arranged in a rectangular structure; the two electric telescopic rods are arranged in total, and the two electric telescopic rods are fixedly arranged at the center of the top of the supporting plate in the supporting device; the mounting plates are fixedly mounted at the tops of the two electric telescopic rods and are arranged in a rectangular plate-shaped structure, and handles are fixedly mounted at the tops of the mounting plates in a bilateral symmetry manner; the protective shell of the protective device is fixedly connected with the top of the mounting plate; the number of the buzzers is two, and the two buzzers are symmetrically arranged on two sides of the protective shell; the anti-collision structure is arranged at the center of the bottom of the mounting plate, and a top plate of the anti-collision structure is fixedly connected with the bottom of the mounting plate through a screw; the pressing block is arranged in a cylindrical structure, a chamfer is arranged at the bottom of the pressing block, and the pressing block is fixedly arranged at the center of the bottom of the top plate; the switch is arranged in a cylindrical structure, is fixedly arranged at the top of the bottom plate and is concentric with the pressing block; the collecting structure is arranged at the bottom of the bottom plate, and a fixing frame of the collecting structure is fixedly connected with the bottom of the bottom plate through a screw; the analyzer body is arranged in the protective device and is arranged between the two rubber pads; the sampling device is provided with three groups, and the sampling device is fixedly arranged on the outer wall of the shell through the mounting seat.

Further, the supporting device also comprises a supporting plate and a reinforcing plate; the supporting plate is arranged in a rectangular plate-shaped structure, and a T-shaped sliding groove is formed in the supporting plate; the number of the reinforcing plates is two, the two reinforcing plates are arranged in an L-shaped structure, and handles are fixedly arranged on the outer sides of the two reinforcing plates; two the welding of gusset plate top has T type lug, and the T type lug of two gusset plates and the T type spout phase-match of backup pad to the T type lug sliding connection at two gusset plate tops is inside the T type spout in the backup pad.

Furthermore, the protection device further comprises a protection shell, a pressing plate, a rubber pad, a top cover and a first spring; the protective shell is of a rectangular structure, and the interior of the protective shell is of a hollow structure; the protective shell is rotatably connected with a top cover through a hinge, and the top cover is fixedly connected with the other end of the protective shell through a lockset; the left and right symmetrical welding of the inside of the protective shell is provided with a first four springs, pressing plates are fixedly mounted on the inner sides of the first four springs, and rubber pads are fixedly mounted on the inner sides of the two pressing plates.

Furthermore, the anti-collision structure further comprises a top plate, a second spring, a bottom plate and a fixing pin; the top plate is arranged in a rectangular plate-shaped structure, and the bottom of the top plate is fixedly provided with fixing pins in a bilateral symmetry manner; the two fixing pins are arranged in a cylindrical structure, and limiting plates are fixedly arranged at the bottoms of the two fixing pins; and a second spring is arranged outside the fixing pin, and the second spring is positioned between the top plate and the bottom plate.

Furthermore, the acquisition structure also comprises a fixed frame, a connecting device, blades, a drill bit and a motor; the motor is fixedly arranged in the fixed frame, and the bottom of the motor is provided with a connecting device; the connecting device is connected with the bottom of the motor through the shell, and the drill bit is fixedly arranged at the bottom of the shell; the blades are fixedly installed on the outer wall of the shell, and the shell is arranged in a spiral structure.

Furthermore, the connecting device also comprises a shell, a handle, a fixing block, a groove, a sliding block, a connecting block, a spring III and a connecting shaft; a groove is formed in the shell in a penetrating mode, and the groove is arranged in a rectangular structure; the handle is connected inside the groove in a sliding mode and is arranged in a rectangular plate-shaped structure; the center of the bottom of the handle is fixedly provided with a connecting shaft, and the connecting shaft is arranged in a cylindrical structure; the sliding blocks are vertically symmetrically and fixedly arranged in the connecting shaft and are arranged in a rectangular structure; fixed blocks are symmetrically and fixedly arranged in the shell up and down, the two fixed blocks are arranged in a cylindrical structure, and the connecting shaft and the two sliding blocks are connected in the two fixed blocks in a sliding manner; the outer wall of the connecting shaft is fixedly provided with a connecting block, and the connecting block is arranged in a cylindrical structure; a third spring is arranged outside the connecting shaft and is positioned between the connecting block and the shell; when the top of the connecting block is tightly attached to the bottom of the fixing block, the handle is positioned at the top of the groove.

Furthermore, the sampling device also comprises a mounting seat, a shell, a cover plate, a fourth spring, a connecting plate and a limiting block; the shell is connected inside the mounting seat in a sliding manner, and limiting blocks are fixedly arranged on two sides of the shell; the bottom of the shell is rotatably connected with a cover plate through a hinge, and the other end of the cover plate is fixedly connected with the shell through a buckle; a connecting plate is fixedly arranged at the bottom of the shell, the connecting plate is in a rectangular plate-shaped structure, and a spring IV is arranged between the connecting plate and the shell; the draft angle on the left side of the shell is set to be 20 degrees, the interior of the shell is of a hollow structure, the bottom of the shell is provided with an inclination, and the inclination is 5 degrees.

Further, the connecting shaft further comprises a fixing plate; three fixed plates are fixedly mounted on one side of the connecting shaft at equal intervals and are arranged in a triangular plate-shaped structure, and the outer sides of the three fixed plates are matched with the die drawing angle on the left side of the shell.

The invention at least comprises the following beneficial effects:

1. the two reinforcing plates are arranged, when the device is used, the supporting plates can be pulled out through the handles, the firmness of the supporting plates on the ground can be enhanced, the shell is not prone to being inclined, the drill bit can be guaranteed to vertically drill into soil, when the device is not used, the two reinforcing plates are folded through the handles, the occupied space is reduced, and turnover of workers is facilitated.

2. When the shell is positioned in soil, a worker presses the handle to enable the connecting shaft to drive the three fixing plates to move downwards, the outer sides of the fixing plates are matched with the left drawing angles of the shell, so that the shell is inserted into the soil, the soil at different depths can be conveniently sampled, the accuracy of data acquisition is guaranteed, when the worker loosens the handle, the connecting shaft moves upwards under the action of the spring III, and the spring IV is arranged between the connecting plate and the shell, so that the shell stretches into the mounting seat after sampling is completed, the sample is guaranteed not to be polluted, the data acquisition requirement is met, and the soil analysis can be conveniently carried out by the worker.

3. According to the arrangement of the pressing plate, the rubber pad and the first spring, when the protective shell is collided and vibrated, the first spring provides acting force for the pressing plate and abuts against the analyzer body through the rubber pad, impact force generated by vibration on the protective shell can be reduced by the reaction force generated by the first spring and the damping effect of the rubber pad, so that the analyzer body can be well protected, the service life of the analyzer body is prolonged, the analyzer body is located in the protective device, a cover plate is opened after sampling is completed to take out a sample, the bottom of the shell is provided with an inclination, the residue of the sample in the shell is avoided, and then the sample is analyzed through the analyzer body, so that a worker can quickly obtain a soil analysis result, the progress of geological survey is accelerated, the structure is reasonable, and the use is convenient.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a schematic front view of the present invention.

Fig. 3 is a schematic view showing the structure of the top cover of the present invention after the top cover is opened and closed and the reinforcing plate is pulled out.

Fig. 4 is a structural schematic diagram of the shell and the vane of the invention after being cut at the center.

Fig. 5 is a schematic bottom plan view of the present invention.

FIG. 6 is a schematic view of the sampling device of the present invention.

Fig. 7 is a partial enlarged structural view of a in fig. 2 according to the present invention.

Fig. 8 is a partial enlarged structural view of B in fig. 4 according to the present invention.

Fig. 9 is a partially enlarged structural view of C in fig. 4 according to the present invention.

Fig. 10 is a partially enlarged structural view of D in fig. 4 according to the present invention.

Fig. 11 is a partially enlarged schematic view of E in fig. 5 according to the present invention.

In the drawings, the corresponding relationship between the component names and the reference numbers is as follows:

1. a support device; 101. a support plate; 102. a reinforcing plate; 2. an electric telescopic rod; 3. mounting a plate; 4. a buzzer; 5. a guard; 501. a protective shell; 502. pressing a plate; 503. a rubber pad; 504. a top cover; 505. a first spring; 6. a handle; 7. an anti-collision structure; 701. a top plate; 702. a second spring; 703. a base plate; 704. a fixing pin; 8. collecting the structure; 801. a fixed mount; 802. a connecting device; 8021. a housing; 8022. a handle; 8023. a fixed block; 8024. a groove; 8025. a slider; 8026. connecting blocks; 8027. a third spring; 8028. a connecting shaft; 80281. a fixing plate; 803. a blade; 804. a drill bit; 805. a motor; 9. briquetting; 10. a switch; 12. an analyzer body; 13. a sampling device; 1301. a mounting seat; 1302. a housing; 1303. a cover plate; 1304. a fourth spring; 1305. a connecting plate; 1306. and a limiting block.

Detailed Description

The embodiments of the present invention will be described in further detail with reference to the drawings and examples. The following examples are intended to illustrate the invention but are not intended to limit the scope of the invention.

In the description of the present invention, "a plurality" means two or more unless otherwise specified; the terms "coaxial," "bottom," "one end," "top," "middle," "other end," "upper," "side," "top," "inner," "front," "center," "two ends," and the like are used in an orientation or positional relationship indicated in the drawings for convenience in describing and simplifying the description, and are not intended to indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the invention. Furthermore, the terms "first," "second," "third," and the like 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 stated or limited otherwise, the terms "mounted," "disposed," "connected," "fixed," "screwed" and the like are to be understood broadly, and for example, they may be fixedly connected, detachably connected, or integrated; can be mechanically or electrically connected; the terms may be directly connected or indirectly connected through an intermediate, and may be communication between two elements or interaction relationship between two elements, unless otherwise specifically limited, and the specific meaning of the terms in the present invention will be understood by those skilled in the art according to specific situations.

Example (b):

as shown in figures 1 to 11:

the invention provides a geological survey big data acquisition and analysis device which comprises a supporting device 1, an electric telescopic rod 2, an installation plate 3, a buzzer 4, a protection device 5, an anti-collision structure 7, an acquisition structure 8, a pressing block 9, a switch 10, an analyzer body 12 and a sampling device 13, wherein the electric telescopic rod is arranged on the supporting device; the two groups of supporting devices 1 are arranged, and the supporting devices 1 are arranged in a rectangular structure; the number of the electric telescopic rods 2 is two, and the two electric telescopic rods 2 are fixedly arranged at the center of the top of the supporting plate 101 in the supporting device 1; the mounting plates 3 are fixedly mounted at the tops of the two electric telescopic rods 2, the mounting plates 3 are arranged in a rectangular plate-shaped structure, and the handles 6 are fixedly mounted at the tops of the mounting plates 3 in a bilateral symmetry manner; the protection device 5 is arranged at the center of the top of the mounting plate 3, and the protection shell 501 of the protection device 5 is fixedly connected with the top of the mounting plate 3; two buzzers 4 are arranged, and the two buzzers 4 are symmetrically arranged on two sides of the protective shell 501; the anti-collision structure 7 is arranged at the center of the bottom of the mounting plate 3, and a top plate 701 of the anti-collision structure 7 is fixedly connected with the bottom of the mounting plate 3 through a screw; the pressing block 9 is arranged in a cylindrical structure, a chamfer is arranged at the bottom of the pressing block 9, and the pressing block 9 is fixedly arranged at the center of the bottom of the top plate 701; the switch 10 is arranged in a cylindrical structure, the switch 10 is fixedly arranged at the top of the bottom plate 703, and the switch 10 and the pressing block 9 are arranged concentrically; the acquisition structure 8 is arranged at the bottom of the bottom plate 703, and a fixing frame 801 of the acquisition structure 8 is fixedly connected with the bottom of the bottom plate 703 through screws; the analyzer body 12 is arranged inside the protective device 5, and the analyzer body 12 is arranged between the two rubber pads 503; the sampling devices 13 are provided with three groups, and the sampling devices 13 are fixedly mounted on the outer wall of the housing 8021 through the mounting seat 1301.

Wherein, the supporting device 1 further comprises a supporting plate 101 and a reinforcing plate 102; the supporting plate 101 is arranged in a rectangular plate-shaped structure, and a T-shaped sliding groove is formed in the supporting plate 101; the number of the reinforcing plates 102 is two, the two reinforcing plates 102 are arranged in an L-shaped structure, and handles are fixedly arranged on the outer sides of the two reinforcing plates 102; the welding of two gusset plates 102 top has T type lug, and the T type lug of two gusset plates 102 and the T type spout phase-match of backup pad 101, and inside the T type spout of the T type lug sliding connection at two gusset plates 102 tops in backup pad 101, the setting of two gusset plates 102, pull out through the handle when using, can strengthen backup pad 101 subaerial fastness, make the difficult emergence of shell 8021 crooked, drill bit 804 has also been guaranteed in can vertical drilling soil, and pack up two gusset plates 102 through the handle when not using, occupation space has been reduced, and be convenient for staff's turnover.

The protection device 5 further comprises a protection shell 501, a pressing plate 502, a rubber pad 503, a top cover 504 and a first spring 505; the protective shell 501 is arranged in a rectangular structure, and the interior of the protective shell 501 is arranged in a hollow structure; the protective shell 501 is rotatably connected with a top cover 504 through a hinge, and the top cover 504 is fixedly connected with the other end of the protective shell 501 through a lock; the inside bilateral symmetry welding of protective housing 501 has four springs 505, and the inboard fixed mounting of four springs 505 has clamp plate 502, and the inboard fixed mounting of two clamp plates 502 has rubber pad 503, clamp plate 502, the setting of rubber pad 503 and spring 505, when protective housing 501 receives the collision and vibrates, effect through spring 505, spring 505 provides the effort to clamp plate 502, and it is inconsistent with analysis appearance body 12 through rubber pad 503, can receive the impact force that the vibration produced at protective housing 501, the reaction force that is produced by spring 505 and the shock attenuation effect of rubber pad 503 subtract, thereby can be fine protect analysis appearance body 12, the service life of analysis appearance body 12 is improved.

The anti-collision structure 7 further comprises a top plate 701, a second spring 702, a bottom plate 703 and a fixing pin 704; the top plate 701 is arranged in a rectangular plate-shaped structure, and fixing pins 704 are fixedly mounted at the bottom of the top plate 701 in a left-right symmetrical mode; the two fixing pins 704 are arranged in a cylindrical structure, and limiting plates are fixedly arranged at the bottoms of the two fixing pins 704; two fixed pin 704 externally mounted have two 702 of springs, and two 702 of springs are located between roof 701 and bottom plate 703, the setting of two 702 of springs, when drill bit 804 bores hard soil or rock, bottom plate 703 rebound this moment, thereby avoided drill bit 804 to take place to damage, and roof 701 bottom center department fixed mounting has briquetting 9, bottom plate 703 top center department fixed mounting has switch 10, when bottom plate 703 rebound, briquetting 9 and switch 10 contact, bee calling organ 4 work this moment, be convenient for indicate the staff, make the staff can in time close equipment, the equipment has been avoided taking place to damage.

Wherein, the collecting structure 8 further comprises a fixing frame 801, a connecting device 802, a blade 803, a drill 804 and a motor 805; a motor 805 is fixedly arranged in the fixing frame 801, and a connecting device 802 is arranged at the bottom of the motor 805; the connecting device 802 is connected with the bottom of the motor 805 through the casing 8021, and the drill bit 804 is fixedly installed at the bottom of the casing 8021; the blade 803 is fixedly installed on the outer wall of the casing 8021, and the casing 8021 is arranged in a spiral structure, the connecting device 802 further comprises the casing 8021, a handle 8022, a fixing block 8023, a groove 8024, a sliding block 8025, a connecting block 8026, a spring 8027 and a connecting shaft 8028; a groove 8024 is formed in the housing 8021 in a penetrating manner, and the groove 8024 is arranged in a rectangular structure; the handle 8022 is slidably connected inside the groove 8024, and the handle 8022 is arranged in a rectangular plate-shaped structure; a connecting shaft 8028 is fixedly arranged at the center of the bottom of the handle 8022, and the connecting shaft 8028 is arranged in a cylindrical structure; the slide blocks 8025 are vertically symmetrically and fixedly installed in the connecting shaft 8028, and the slide blocks 8025 are arranged in a rectangular structure; fixed blocks 8023 are vertically and symmetrically fixedly mounted in the housing 8021, the two fixed blocks 8023 are arranged in a cylindrical structure, and the connecting shaft 8028 and the two sliding blocks 8025 are slidably connected in the two fixed blocks 8023; the outer wall of the connecting shaft 8028 is fixedly provided with a connecting block 8026, and the connecting block 8026 is arranged in a cylindrical structure; a spring three 8027 is arranged outside the connecting shaft 8028, and the spring three 8027 is positioned between the connecting block 8026 and the housing 8021; when the top of the connecting block 8026 is closely attached to the bottom of the fixing block 8023, the handle 8022 is located at the top of the groove 8024, and the sampling device 13 further comprises a mounting base 1301, a housing 1302, a cover plate 1303, a spring IV 1304, a connecting plate 1305 and a limiting block 1306; the shell 1302 is slidably connected inside the mounting base 1301, and limiting blocks 1306 are fixedly mounted on two sides of the shell 1302; the bottom of the shell 1302 is rotatably connected with a cover plate 1303 through a hinge, and the other end of the cover plate 1303 is fixedly connected with the shell 1302 through a buckle; a connecting plate 1305 is fixedly installed at the bottom of the case 1302, the connecting plate 1305 is arranged in a rectangular plate-shaped structure, and a spring four 1304 is installed between the connecting plate 1305 and the shell 8021; the draft angle on the left side of the housing 1302 is set to be 20 °, the interior of the housing 1302 is a hollow structure, the bottom of the housing 1302 is provided with an inclination which is 5 °, and the connecting shaft 8028 further comprises a fixing plate 80281; three fixing plates 80281 are fixedly installed on one side of the connecting shaft 8028 at equal intervals, three fixing plates 80281 are arranged in a triangular plate-shaped structure, the outer sides of the three fixing plates 80281 are matched with the left drawing angle of the shell 1302, when the shell 8021 is positioned in soil, a worker presses the handle 8022 to enable the connecting shaft 8028 to drive the three fixing plates 80281 to move downwards, the outer sides of the fixing plates 80281 are matched with the left drawing angle of the shell 1302, so that the shell 1302 is inserted into the soil to facilitate sampling of the soil at different depths, the accuracy of data acquisition is guaranteed, when the worker loosens the handle 8022, the connecting shaft 8028 moves upwards under the action of the spring three 8027, and the spring four 1304 is installed between the connecting plate 1305 and the shell 8021, so that the shell 1302 stretches into the mounting seat 1301 after sampling is completed, the sample is guaranteed not to be polluted, and the data acquisition requirements are met, the soil analysis is convenient for the staff.

The specific use mode and function of the embodiment are as follows:

when the drill bit 804 is used, firstly, a worker connects the drill bit with an external power supply, then the drill bit is placed at a proper position through the two handles 6, then the worker pulls out the reinforcing plates 102 through the handles, the firmness of the supporting plate 101 on the ground can be enhanced, the shell 8021 is not easy to skew, the drill bit 804 can be ensured to vertically drill into the soil, the two reinforcing plates 102 are folded through the handles when the drill bit 804 is not used, the occupied space is reduced, the turnover of the worker is facilitated, then the motor 805 and the electric telescopic rod 2 are started, when the drill bit 804 drills to hard soil or rock, the bottom plate 703 moves upwards, the drill bit 804 is prevented from being damaged, the pressing block 9 is fixedly installed at the center of the bottom of the top plate 701, the switch 703 is fixedly installed at the center of the top of the bottom plate, and when the bottom plate 703 moves upwards, the pressing block 9 is in contact with, at the moment, the buzzer 4 works to prompt a worker, so that the worker can close the device in time and avoid the device from being damaged, when the shell 8021 is positioned in the soil, the worker closes the power supply of the invention, then the worker presses the handle 8022 to enable the connecting shaft 8028 to drive the three fixing plates 80281 to move downwards, the outer side of the fixing plate 80281 is matched with the drawing angle on the left side of the shell 1302, so that the shell 1302 is inserted into the soil to sample the soil at different depths, the accuracy of data acquisition is ensured, when the worker loosens the handle 8022, the connecting shaft 8028 moves upwards under the action of the spring three 8027, and the spring four 1304 is arranged between the connecting plate 1305 and the shell 8021, so that the shell 1302 stretches into the mounting seat 1301 after sampling is completed, the sample is ensured not to be polluted, and the data acquisition requirement is met, the staff of being convenient for carries out soil analysis, opens apron 1303 and takes out the sample after the sample is accomplished to casing 1302 bottom is provided with the inclination, and the inclination is 5, has avoided the residue of the inside sample of casing 1302, then carries out the analysis with the sample through analysis appearance body 12, and the staff of being convenient for learns soil analysis result fast for geological survey's progress.

The invention is not described in detail, but is well known to those skilled in the art.

The embodiments of the present invention have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the invention in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiment was chosen and described in order to best explain the principles of the invention and the practical application, and to enable others of ordinary skill in the art to understand the invention for various embodiments with various modifications as are suited to the particular use contemplated.

Claims

1. A geological survey big data acquisition analytical equipment which characterized in that: the device comprises a supporting device (1), an electric telescopic rod (2), a mounting plate (3), a buzzer (4), a protective device (5), an anti-collision structure (7), a collection structure (8), a pressing block (9), a switch (10), an analyzer body (12) and a sampling device (13); the two groups of supporting devices (1) are arranged, and the supporting devices (1) are arranged in a rectangular structure; the number of the electric telescopic rods (2) is two, and the two electric telescopic rods (2) are fixedly arranged at the center of the top of a supporting plate (101) in the supporting device (1); the mounting plates (3) are fixedly mounted at the tops of the two electric telescopic rods (2), the mounting plates (3) are arranged in a rectangular plate-shaped structure, and handles (6) are fixedly mounted at the tops of the mounting plates (3) in a bilateral symmetry manner; the protection device (5) is arranged at the center of the top of the mounting plate (3), and a protection shell (501) of the protection device (5) is fixedly connected with the top of the mounting plate (3); the number of the buzzers (4) is two, and the two buzzers (4) are symmetrically arranged on two sides of the protective shell (501); the anti-collision structure (7) is arranged at the center of the bottom of the mounting plate (3), and a top plate (701) of the anti-collision structure (7) is fixedly connected with the bottom of the mounting plate (3) through a screw; the pressing block (9) is arranged in a cylindrical structure, a chamfer is arranged at the bottom of the pressing block (9), and the pressing block (9) is fixedly arranged at the center of the bottom of the top plate (701); the switch (10) is arranged in a cylindrical structure, the switch (10) is fixedly arranged at the top of the bottom plate (703), and the switch (10) and the pressing block (9) are arranged concentrically; the acquisition structure (8) is arranged at the bottom of the bottom plate (703), and a fixing frame (801) of the acquisition structure (8) is fixedly connected with the bottom of the bottom plate (703) through a screw; the analyzer body (12) is arranged inside the protective device (5), and the analyzer body (12) is arranged between the two rubber pads (503); the sampling devices (13) are provided with three groups, and the sampling devices (13) are fixedly arranged on the outer wall of the shell (8021) through the mounting seat (1301).

2. The geologic survey big data collection and analysis facility of claim 1 wherein: the supporting device (1) further comprises a supporting plate (101) and a reinforcing plate (102); the supporting plate (101) is arranged in a rectangular plate-shaped structure, and a T-shaped sliding groove is formed in the supporting plate (101); the number of the reinforcing plates (102) is two, the two reinforcing plates (102) are arranged in an L-shaped structure, and handles are fixedly arranged on the outer sides of the two reinforcing plates (102); t-shaped convex blocks are welded at the tops of the two reinforcing plates (102), the T-shaped convex blocks of the two reinforcing plates (102) are matched with the T-shaped sliding grooves of the supporting plate (101), and the T-shaped convex blocks at the tops of the two reinforcing plates (102) are connected inside the T-shaped sliding grooves in the supporting plate (101) in a sliding mode.

3. The geologic survey big data collection and analysis facility of claim 1 wherein: the protection device (5) further comprises a protection shell (501), a pressing plate (502), a rubber pad (503), a top cover (504) and a first spring (505); the protective shell (501) is arranged in a rectangular structure, and the interior of the protective shell (501) is arranged in a hollow structure; the protective shell (501) is rotatably connected with a top cover (504) through a hinge, and the top cover (504) is fixedly connected with the other end of the protective shell (501) through a lockset; the protective shell (501) is internally and bilaterally symmetrically welded with four first springs (505), pressing plates (502) are fixedly mounted on the inner sides of the four first springs (505), and rubber pads (503) are fixedly mounted on the inner sides of the two pressing plates (502).

4. The geologic survey big data collection and analysis facility of claim 1 wherein: the anti-collision structure (7) further comprises a top plate (701), a second spring (702), a bottom plate (703) and a fixing pin (704); the top plate (701) is arranged in a rectangular plate-shaped structure, and fixing pins (704) are fixedly mounted at the bottom of the top plate (701) in a bilateral symmetry manner; the two fixing pins (704) are arranged in a cylindrical structure, and limiting plates are fixedly arranged at the bottoms of the two fixing pins (704); and a second spring (702) is arranged outside the two fixing pins (704), and the second spring (702) is positioned between the top plate (701) and the bottom plate (703).

5. The geologic survey big data collection and analysis facility of claim 1 wherein: the acquisition structure (8) further comprises a fixing frame (801), a connecting device (802), a blade (803), a drill bit (804) and a motor (805); a motor (805) is fixedly installed in the fixing frame (801), and a connecting device (802) is arranged at the bottom of the motor (805); the connecting device (802) is connected with the bottom of the motor (805) through the shell (8021), and the drill bit (804) is fixedly arranged at the bottom of the shell (8021); the blades (803) are fixedly arranged on the outer wall of the shell (8021), and the shell (8021) is arranged in a spiral structure.

6. The geologic survey big data collection and analysis facility of claim 5 wherein: the connecting device (802) further comprises a shell (8021), a handle (8022), a fixing block (8023), a groove (8024), a sliding block (8025), a connecting block (8026), a spring III (8027) and a connecting shaft (8028); a groove (8024) is formed in the shell (8021) in a penetrating manner, and the groove (8024) is arranged in a rectangular structure; the handle (8022) is connected inside the groove (8024) in a sliding manner, and the handle (8022) is arranged in a rectangular plate-shaped structure; a connecting shaft (8028) is fixedly arranged at the center of the bottom of the handle (8022), and the connecting shaft (8028) is arranged in a cylindrical structure; the slide blocks (8025) are vertically symmetrically and fixedly arranged in the connecting shaft (8028), and the slide blocks (8025) are arranged in a rectangular structure; fixed blocks (8023) are vertically and symmetrically fixedly mounted in the shell (8021), the two fixed blocks (8023) are arranged in a cylindrical structure, and the connecting shaft (8028) and the two sliding blocks (8025) are connected in the two fixed blocks (8023) in a sliding manner; the connecting block (8026) is fixedly installed on the outer wall of the connecting shaft (8028), and the connecting block (8026) is arranged in a cylindrical structure; a third spring (8027) is arranged outside the connecting shaft (8028), and the third spring (8027) is positioned between the connecting block (8026) and the shell (8021); when the top of the connecting block (8026) is closely attached to the bottom of the fixing block (8023), the handle (8022) is positioned at the top of the groove (8024).

7. The geologic survey big data collection and analysis facility of claim 1 wherein: the sampling device (13) further comprises a mounting seat (1301), a shell (1302), a cover plate (1303), a spring four (1304), a connecting plate (1305) and a limiting block (1306); the shell (1302) is connected inside the mounting base (1301) in a sliding mode, and limiting blocks (1306) are fixedly mounted on two sides of the shell (1302); the bottom of the shell (1302) is rotatably connected with a cover plate (1303) through a hinge, and the other end of the cover plate (1303) is fixedly connected with the shell (1302) through a buckle; a connecting plate (1305) is fixedly installed at the bottom of the shell (1302), the connecting plate (1305) is arranged in a rectangular plate-shaped structure, and a spring four (1304) is installed between the connecting plate (1305) and the shell (8021); the draft angle on the left side of the shell (1302) is set to be 20 degrees, the interior of the shell (1302) is a hollow structure, the bottom of the shell (1302) is provided with a slope, and the slope is 5 degrees.

8. The geologic survey big data collection and analysis facility of claim 6 wherein: the connecting shaft (8028) further comprises a fixing plate (80281); three fixing plates (80281) are fixedly mounted on one side of the connecting shaft (8028) at equal intervals, the three fixing plates (80281) are arranged in a triangular plate-shaped structure, and the outer sides of the three fixing plates (80281) are matched with the die drawing angle on the left side of the shell (1302).