CN111610056A - 5G technology big data-based acquisition equipment - Google Patents

Abstract

The invention belongs to the technical field of sampling, and particularly relates to 5G technology-based big data acquisition equipment, which comprises a supporting seat, wherein a driving assembly and an acquisition assembly are arranged above the supporting seat; the drive assembly includes first drive assembly, first drive assembly with gather the assembly and connect, first drive assembly include first drive mechanism, the first mounting panel that is parallel to each other and second mounting panel gather the assembly and include sample part and rather than the screening part of being connected, and sample part includes the sampling tube, the inside thief rod that is equipped with of sampling tube, the upper end of thief rod is connected with and is used for driving thief rod pivoted motor, the motor with the second slider passes through the connecting rod and connects, and the bottom fixedly connected with sample drill bit of thief rod. The invention can conveniently drill and sample deep soil, avoids the collected sample from being extruded when being taken, and improves the accuracy of the detection result.

Description

5G technology big data-based acquisition equipment

Technical Field

The invention belongs to the technical field of sampling, and particularly relates to a 5G technology-based big data acquisition device.

Background

Big data in the telecommunication field, along with the rapid development of the domestic 4G network and the explosive growth of the mobile internet and the intelligent terminal, compels three mobile communication operators to urgently need to effectively manage the mobile communication network by a big data technology means so as to improve the whole operation efficiency, and a big data mobile network deep mining system (deep mining for short), which is introduced from the aspects of a big data logic architecture, a system architecture and the like:

1. deeplan logic architecture

The logic architecture is divided into three parts: the system comprises a telecommunication big data platform, a telecommunication big data algorithm engine and big data visualization.

Telecommunication big data platform: a data processing platform of a telecommunication big data platform is mainly responsible for Extraction, Transformation and loading of mass data, bears the pressure of high-dimensional complex TB-level data cleaning, and mainly collects communication signaling data packets such as wireless network traffic statistics STS, a core network Gb port, an IuPS port and an S1 port, communication states of network elements and network element topology data. After data extraction and uniform format conversion, the relational data are directly loaded to a central data warehouse (PostgreSQL database cluster), the complex relational data are loaded to a Hadoop cluster, and the waiting algorithm engine further utilizes the distributed computing processing classification of a MapReduce framework in the Hadoop. The final result data predicted by the big data algorithm engine is simplified, visualized and transparent in a data visualization presentation mode through a big data display platform, so that big data information is clear at a glance.

2. The deep data deep platform of the deep deployment architecture is built by the advanced R language + Hadoop architecture + J2EE platform in the industry, and project progress is promoted by adopting an agile practice mode. After the unstructured data are processed by a big data algorithm engine, combing valuable data, and finally entering a PostgreSQL database cluster for displaying by a big data visualization module.

The Deeplan platform performance has: 1. system storage capacity; 2. system response capability; 3. the reliability of the system; 4. network compatibility; 5. the algorithm accuracy; 6. the robustness of the algorithm; 7. the algorithm is dynamic; 8. and (4) algorithm expansibility.

Along with the development of big data technology, the data acquisition device is also very important for big data processing, the data acquisition device on the market at present has low economical and practical performance, poor reliability and inconvenient carrying, and has problems in the use process, such as inconvenient use at night; therefore, it is necessary to develop a new data acquisition device.

The collection of soil samples is basic work in the fields of soil analysis research, geological survey and the like, and the actual conditions of soil are known through analyzing and researching the soil samples. At present, the soil sample collection method includes an earth boring method, a cutting ring method and the like, wherein the soil sample collected by the cutting ring method is mostly applied to the measurement of the volume weight of the soil, and the soil sample collected by the earth boring method is mostly applied to the measurement of the physical, chemical and biological properties of the soil.

The comparison document 1 discloses a soil sampling device, with application number 201520501643.4, which comprises a travelling crane frame and a traction connecting piece at the front end of the travelling crane frame, wherein the travelling crane frame is provided with a soil sampler and a soil sampling funnel matched with the soil sampler; a crank connecting rod mechanism is arranged on the soil taking funnel, a conveying chain with a conveying chain wheel is arranged below the soil taking funnel, and a soil collecting barrel is arranged on the conveying chain; a soil-taking shovel is arranged below the soil-taking device, and a soil-shifting rod is arranged on the soil-taking shovel. The automatic sampler is a complete machine of the automatic sampler, has higher cost and poorer adaptability, easily causes mutual contamination of soil samples, and increases sampling errors.

The comparison document 2 discloses an electric soil sampler, with application number 201420715422.2, which comprises a sampling mechanism, a power mechanism, a transmission mechanism, a drill handle mechanism and a frame, wherein the sampling mechanism comprises a cylindrical hollow drill body, a drill handle and an air hole, and the surface of the cylindrical hollow drill body is provided with scales along the axial direction; a drawer type strip sealing cover is axially arranged on the cylindrical hollow drill body; the outer circumferential surface of the cylindrical hollow drill body is provided with spiral cutting blades along the axial direction, and the spiral cutting blades are consistent with the advancing direction of the sawteeth. The soil drill is mainly of a mechanical structure of a soil drill body and cannot automatically complete control and multiple sampling, the soil drill is of an integral structure and cannot obtain in-situ soil, so that the property of the soil is changed, layering cannot be performed according to the characteristic property of the soil, the analysis result of a soil sample is influenced to a certain extent, and the analysis result is deviated from the actual analysis result.

Disclosure of Invention

Aiming at the defects in the prior art, the invention provides the acquisition equipment based on the 5G technology big data, which can conveniently drill and sample deep soil and avoid the collected sample from being extruded when being taken, thereby ensuring the integrity of the soil sample and improving the accuracy of the detection result.

In order to solve the technical problems, the invention adopts the following technical scheme:

the 5G technology-based big data acquisition equipment comprises a supporting seat, wherein a driving assembly and an acquisition assembly are arranged above the supporting seat;

the drive assembly comprises a first drive assembly, the first drive assembly is connected with the acquisition assembly, the first drive assembly comprises a first transmission mechanism, a first mounting plate and a second mounting plate which are parallel to each other, the first mounting plate and the second mounting plate are mounted above the supporting seat, a plurality of mounting columns are mounted on the left side and the right side of the first mounting plate, a longitudinal slide rail is arranged on the second mounting plate, a first sliding block is connected in the longitudinal slide rail in a sliding manner, a transverse slide rail is arranged between the first mounting plate and the second mounting plate, a second sliding block is connected with the second sliding block, the second sliding block is connected with the first transmission mechanism, the first transmission mechanism drives the second sliding block to slide relative to the transverse slide rail, and the first sliding block slides relative to the longitudinal slide rail simultaneously, one end of the first sliding block, which is far away from the second sliding block, is connected with the acquisition assembly;

gather the assembly including sample part and rather than the screening part of being connected, sample part includes the sampling tube, the inside sample rod that is equipped with of sampling tube, the upper end of sample rod is connected with and is used for the drive the sample rod pivoted motor, the motor with the second slider passes through the connecting rod and connects, the bottom fixedly connected with sample drill bit of sample rod.

The sampling rod above the collection assembly is operated to reciprocate up and down through the driving assembly, the first transmission mechanism drives the second sliding block to slide relative to the transverse sliding rail, the first sliding block is connected with the second sliding block in a sliding mode, the transverse sliding rail is only connected with the second sliding block, the first sliding block slides up and down along the longitudinal sliding rail simultaneously, the sampling rod reciprocates up and down due to the fact that the first sliding block is connected with a motor connected with the sampling rod through a connecting rod, and when the first sliding block moves to the bottommost end of the longitudinal sliding rail, the sampling drill bit drills soil downwards to the limit depth.

Preferably, the sampling rod is provided with a spiral hinge upwards from the connection part of the sampling rod and the sampling drill bit.

When the sampling rod does up-and-down reciprocating motion, the spiral twisting blade brings the soil drilled by the sampling drill bit into the sampling cylinder.

Preferably, the first transmission mechanism comprises three transmission wheels, the three transmission wheels are installed on the first installation plate through installation columns on the first installation plate, the three transmission wheels form an acute triangle, the three transmission wheels are connected through a belt in a transmission mode, the belt is connected with the second sliding block through a cross rod, and the belt drives the second sliding block to move synchronously.

Because the three driving wheels form an acute triangle, the belt drives the movement direction of the second slide rail to be oblique line instead of horizontal line, and can be divided into movement in the horizontal direction and movement in the vertical direction, namely the movement of the first slide block in the vertical direction and the movement of the second slide block in the horizontal direction, the up-and-down movement of the sampling rod is realized, and the time required by the sampling rod to do one up-and-down reciprocating movement is limited.

Preferably, an anti-skid wheel is further arranged between the three driving wheels, and the anti-skid wheel is also in synchronous transmission connection with the belt.

When the belt drives three drive wheel and rotates, take place to slide easily, set up the emergence that anti-skidding wheel can reduce this kind of condition, prevent the accident at the sampling process.

Preferably, the screening part includes first screening portion and second screening portion, first screening portion includes a screening section of thick bamboo and the first screening subassembly that both ends run through, first screening subassembly is established inside the screening section of thick bamboo, screening section of thick bamboo one end with the sampling section of thick bamboo is connected, the other end and the second screening portion of screening section of thick bamboo are connected, just screening section of thick bamboo from with sampling section junction orientation the downward sloping of second screening portion.

And carrying out batch and classified collection on the sampled soil by utilizing the first screening part and the second screening part.

Preferably, the first screening assembly comprises a first screening disc and a second screening disc, the first screening disc is arranged above the second screening disc, when the sampled soil enters the screening cylinder through the sampling rod, the sampled soil firstly passes through the first screening disc, the first screening disc is fixedly connected with the inner wall of the first screening disc, the second screening disc is installed in the screening cylinder through a connecting shaft, the connecting shaft penetrates through the first screening disc, the connecting shaft is movably connected with the first screening disc, the switching shaft is fixedly connected with the second screening disc, the first screening holes are formed in the first screening disc and a plurality of second screening discs, the first screening holes in the first screening disc and the first screening holes in the second screening disc are located on the same axis, and the second screening disc is further provided with second screening holes, the surface of the second screening hole is covered with a water filtering net, the size of the second screening hole is smaller than that of the first screening hole, and the connecting shaft is connected with a driving motor.

Soil obtained by sampling enters the screening barrel through the sampling barrel, the screening barrel inclines downwards from the joint of the screening barrel and the sampling barrel to the second screening part, the soil can move downwards under the action of gravity of the soil, the soil firstly passes through the first screening holes on the first screening plate, the first screening holes limit the passage of larger soil, the driving motor drives the connecting shaft to rotate, the second screening plate is connected with the connecting shaft, the second screening plate moves synchronously along with the connecting shaft, when the first screening holes on the second screening disc are aligned with the first screening holes on the first screening disc, the soil above the first screening disc enters the second screening part through the second screening disc, the soil moisture content of the soil is high, and when the first screening holes are not aligned with the first screening holes on the first screening plate, only the soil enters the second screening part through the second screening holes.

Preferably, the connecting axle surface is equipped with one end external screw thread, open at first screening dish center has the internal thread hole, just the external screw thread of connecting axle surface with internal thread hole screw-thread fit on the first screening dish.

The connecting shaft is in threaded fit with the first screening disc, when the driving motor controls the connecting shaft to rotate forwards, the second threaded disc moves towards the first threaded disc under the action of the threads, at the moment, soil between the first screening disc and the second screening disc is extruded, most of water is extruded, and the extruded water enters the second screening part through the second screening holes.

Preferably, second screening portion includes the storage tray, open the storage tray top has a plurality of holding holes, and the collecting pipe has all been placed in every holding hole, the storage tray is located under the end of screening section of thick bamboo, the below of storage tray is connected with eccentric rim plate, eccentric rim plate is connected with second drive mechanism, the drive of second drive mechanism eccentric rim plate rotates.

When the eccentric wheel disc rotates, the collecting discs on the collecting disc sequentially and one under the screening cylinder are changed, the rotating interval of the eccentric wheel disc is controlled, so that the collecting amount in each collecting pipe is controlled to be equal, and because of relative motion between the first screening disc and the second screening disc, in two adjacent collecting pipes, only liquid water obtained by filtering is contained in each collecting pipe, and soil obtained by the other collecting pipe after screening is obtained.

Preferably, the sampling cylinder is provided with a primary treatment mechanism, the primary treatment mechanism comprises a first connecting disc and a second connecting disc, the first connecting disc is connected with a motor, the second connecting disc is arranged below the first connecting disc, a through hole is formed in the gravity center of the second connecting disc, the sampling rod penetrates through the through hole to be connected with the motor above the first connecting disc, a treatment hole is formed in the outer edge of the second connecting disc, the lower part of the treatment hole is connected with the sieving cylinder through a hose, a scraper is arranged between the first connecting disc and the second connecting disc and is fixedly connected with the sampling rod, a plurality of arc grooves are formed in the upper part of the first connecting disc, the first connecting disc is connected with the first connecting disc through a plurality of support columns, the lower end of each support column is fixedly connected with the second connecting disc, and the upper end of each support column penetrates through the arc grooves of the first connecting disc, and the upper ends of the support columns are connected with the arc-shaped grooves in a sliding mode, and any support column is connected through a third transmission mechanism.

When the sampling drill bit drills soil, the soil brought into the sampling cylinder through the spiral reamer blade may contain some large stones and may also contain large soil blocks, the large stones and the large soil blocks are removed through the primary treatment mechanism, a scraper is arranged between the first connecting disc and the second connecting disc, the scraper rotates synchronously along with the sampling rod, the first connecting disc and the second connecting disc are connected through the support column, any support column driven by the third transmission mechanism slides in the arc-shaped groove, the second connecting disc is fixedly connected with the support column, the second connecting disc can rotate in a reciprocating mode along with the back and forth of the support column in the arc-shaped groove, the rotating angle is an acute angle, under the relative motion of the second connecting disc and the scraper, primary treatment is conducted on the soil on the second connecting disc, and the large soil blocks are refined.

Preferably, the third transmission mechanism includes a first transmission shaft, one end of the first transmission shaft is fixedly connected to the pillar, the upper end of the first transmission shaft is connected to a second transmission shaft, the other end of the second transmission shaft is fixedly connected to a rotating shaft, and the first transmission shaft and the second transmission shaft form an "L" shape.

Preferably, the screening cylinder is provided with a funnel at the tail end, and the lower part of the funnel is opposite to the pipe orifice of the collecting pipe.

And the soil or liquid level obtained after screening is accurately conveyed into a collecting pipe through a funnel.

Preferably, an inner container is further arranged in the screening cylinder, and a controller, a configuration manager, a plurality of data processors, a memory and a storage battery are arranged in the inner container; the data acquisition interfaces are respectively connected with the data processors in the liner, the data processors are connected with the configuration manager, and the configuration manager, the storage battery and the data output interface are all connected with the controller.

The working principle and the advantages of the invention are as follows:

(1) according to the scheme, the soil sample collection amount and purity at the preset depth can be improved, so that the final detection accuracy is improved;

(2) the problem that the sample analysis result is influenced by changing the self property and layering of soil in the sampling process is effectively solved;

(3) the sampling cylinder is enabled to enter the soil in a vertical direction, so that the problem that the soil sample is not accurately collected due to the inclination of the sampling cylinder is effectively prevented;

(4) the soil obtained by sampling is subjected to batch and classified collection by utilizing a first screening part and a second screening part;

(5) when the sampling drill bit drills soil, the soil brought into the sampling cylinder through the spiral blade may contain some large stones and also may contain larger soil blocks, the large stones and the large soil blocks are removed through the primary treatment mechanism, the soil on the second connecting disc is subjected to primary treatment under the relative motion of the second connecting disc and the scraper, and the larger soil blocks are refined;

(4) by utilizing the 5G technology for big data, data information can be backed up, so that the safety and the effectiveness of the data are ensured; the data information can be synchronously transmitted while the data information is collected.

Drawings

FIG. 1 is a general structure diagram of a 5G technology-based big data acquisition device of the present invention;

FIG. 2 is a general structure diagram of a drive assembly in a 5G technology-based big data acquisition device according to the present invention;

FIG. 3 is a partial structural diagram of a drive assembly in a 5G technology-based big data acquisition device according to the present invention;

FIG. 4 is a structural diagram of a first transmission mechanism in the 5G technology-based big data acquisition equipment of the invention;

FIG. 5 is an internal structural diagram of a sampling component in the 5G technology-based big data acquisition equipment of the present invention;

FIG. 6 is a diagram of the internal structure of a sampling component in the 5G technology big data-based acquisition equipment (with the protective shell removed);

FIG. 7 is a cross-sectional view of a screening barrel in a 5G technology big data based acquisition device of the present invention;

FIG. 8 is an internal structure diagram of a screening barrel in the 5G technology-based big data acquisition equipment of the present invention;

FIG. 9 is a schematic structural diagram of a second screening part in the 5G technology-based big data acquisition equipment.

Reference numerals referred to in the drawings are: the device comprises a supporting seat 1, a driving assembly 2, a first mounting plate 201, a second mounting plate 202, a mounting column 203, a driving wheel 204, a belt 205, a transverse sliding rail 206, a second sliding block 207, a first sliding block 208, a longitudinal sliding rail 209, a connecting rod 210, an anti-skidding wheel 211, a cross rod 212, a sampling part 3, a protective shell 301, an anti-sticking thorn 301a, a sampling drill bit 302, a sampling rod 303, a spiral hinge blade 304, a second connecting disk 306, a first connecting disk 307, an arc-shaped groove 307a, a supporting column 308, a first transmission shaft 309, a second transmission shaft 310, a sampling cylinder 3A, a first sieving part 4, a sieving cylinder 4A, a connecting shaft 401, a second sieving disk 402, a first sieving disk, a first sieving hole 404, a second sieving hole 405, a funnel 406, a second sieving part 5, a containing disk 501, a collecting pipe 502, an eccentric wheel disk 503 and a second transmission mechanism 504.

Detailed Description

In order that those skilled in the art can better understand the present invention, the technical solutions of the present invention are further described below with reference to the drawings and examples.

Example one

As shown in fig. 1 to 8, the 5G technology-based big data acquisition device of the present invention includes a support base 1, a driving assembly 2 and an acquisition assembly are disposed above the support base 1;

the driving assembly 2 comprises a first driving assembly, the first driving assembly is connected with the acquisition assembly, the first driving assembly comprises a first transmission mechanism, a first mounting plate 201 and a second mounting plate 202 which are parallel to each other, the first mounting plate 201 and the second mounting plate 202 are mounted on the left side and the right side of the first mounting plate 201 above the supporting seat 1, a plurality of mounting columns 203 are mounted on the left side and the right side of the first mounting plate 201, the second mounting plate 202 is provided with a longitudinal slide rail 209, a first slide block 208 is connected in the longitudinal slide rail 209 in a sliding manner, a transverse slide rail 206 is arranged between the first mounting plate 201 and the second mounting plate 202, the transverse slide rail 206 is connected with a second slide block 207 in a sliding manner, the second slide block 207 is connected with the first slide block 208, the second slide block is connected with the first transmission mechanism, the first, meanwhile, the first sliding block 208 slides relative to the longitudinal sliding rail 209, and one end of the first sliding block 208, which is far away from the second sliding block 207, is connected with the acquisition assembly;

gather the assembly including sampling component 3 and rather than the screening part of being connected, sampling component 3 includes sampler barrel 3A, the inside sample rod 303 that is equipped with of sampler barrel 3A, the outside cover of sample rod 303 has protective housing 301, be equipped with antiseized thorn 301a on the protective housing, prevent that soil from gluing on the protective housing, the upper end of sample rod 303 is connected with and is used for driving sample rod 303 pivoted motor, the motor passes through connecting rod 210 with second slider 207 and is connected, the bottom fixedly connected with sample drill bit 302 of sample rod 303.

The sampling rod 303 above the collection assembly is operated to reciprocate up and down through the driving assembly 2, the first transmission mechanism drives the second sliding block 207 to slide relative to the transverse sliding rail 206, the first sliding block 208 is connected with the second sliding block 207 in a sliding manner, the transverse sliding rail 206 is only connected with the second sliding block 207, the first sliding block 208 slides up and down along the longitudinal sliding rail 209 simultaneously, the first sliding block 208 is connected with a motor connected with the sampling rod 303 through a connecting rod 210, the sampling rod 303 reciprocates up and down, when the first sliding block 208 moves to the bottom end of the longitudinal sliding rail 209, the sampling drill 302 drills soil downwards to the limit depth, and the sampling rod 303 is upwards provided with a spiral hinge blade 304 from the connection part with the sampling drill 302. When the sampling rod 303 reciprocates up and down, the helical twisting blade 304 brings the soil drilled by the sampling drill 302 into the sampling cylinder 3A.

The first transmission mechanism comprises three transmission wheels 204, the three transmission wheels 204 are arranged on the first mounting plate 201 through mounting posts 203 on the first mounting plate 201, the three transmission wheels 204 form an acute triangle, the three transmission wheels 204 are in transmission connection through a belt 205, the belt 205 is connected with the second sliding block 207 through a cross rod 212, and the belt 205 drives the second sliding block 207 to move synchronously.

Because the three driving wheels 204 form an acute triangle, the movement direction of the belt 205 driving the second sliding rail is an oblique line instead of a horizontal line, and can be divided into movement in the horizontal direction and movement in the vertical direction, that is, the movement of the first sliding block 208 in the vertical direction and the movement of the second sliding block 207 in the horizontal direction, and the up-and-down movement of the sampling rod 303 is realized, the time required by the up-and-down reciprocating movement of the sampling rod 303 is also limited, an anti-skid wheel 211 is further arranged between the three driving wheels 204, and the anti-skid wheel 211 is also in synchronous transmission connection with the belt 205.

When the belt 205 drives three drive wheel 204 and rotates, take place to slide easily, it can reduce the emergence of this kind of condition to set up anti-skidding wheel 211, prevent the accident at sampling process, the screening part includes first screening portion 4 and second screening portion 5, first screening portion 4 includes screening section of thick bamboo 4A and the first screening subassembly that two run through, first screening subassembly is established inside screening section of thick bamboo 4A, screening section of thick bamboo 4A one end is connected with sampling tube 3A, screening section of thick bamboo 4A's the other end is connected with second screening portion 5, and screening section of thick bamboo 4A inclines down towards second screening portion 5 from the junction with sampling tube 3A, utilize first screening portion 4 and second screening portion 5 to carry out batching, the categorised collection to the soil that the sampling obtained.

The first screening assembly comprises a first screening disc 403 and a second screening disc 402, the first screening disc 403 is arranged above the second screening disc 402, sampled soil enters the screening cylinder 4A through the sampling rod 303, the sampled soil firstly passes through the first screening disc 403, the first screening disc 403 is fixedly connected with the inner wall of the first screening disc 403, the second screening disc 402 is arranged in the screening cylinder 4A through a connecting shaft 401, the connecting shaft 401 penetrates through the first screening disc 403, the connecting shaft 401 is movably connected with the first screening disc 403, the switching shaft is fixedly connected with the second screening disc 402, the first screening holes 404 are formed in the first screening disc 403 and the plurality of second screening discs 402, the first screening holes 404 in the first screening disc 403 and the first screening holes 404 in the second screening disc 402 are on the same axis, the second screening disc 402 is further provided with second screening holes 405, and the surface of the second screening holes 405 is covered with a water filtering net, the second screening holes 405 are smaller than the first screening holes 404, and the connecting shaft 401 is connected with a driving motor.

The soil obtained by sampling enters the screening cylinder 4A through the sampling cylinder, because the screening cylinder 4A inclines downwards from the joint with the sampling cylinder 3A towards the second screening part 5, the soil can move downwards under the action of the gravity of the soil, the soil firstly passes through the first screening holes 404 on the first screening disc 403, the first screening holes 404 limit the passing of larger soil, the driving motor drives the connecting shaft 401 to rotate, the second screening disc 402 is connected with the connecting shaft 401, the second screening disc 402 moves synchronously along with the connecting shaft 401, when the first screening holes 404 on the second screening disc 402 are aligned with the first screening holes 404 on the first screening disc 403, the soil above the first screening disc 403 enters the second screening part 5 through the second screening disc 402, the soil moisture content of the soil is high, and the first screening holes 404 are not aligned with the first screening holes 404 on the first screening disc 403, only the soil passes through the second screening holes 405 into the second screening portion 5.

The second sieving part 5 comprises a receiving disc 501, a plurality of receiving holes are formed in the upper portion of the receiving disc 501, a collecting pipe 502 is placed in each receiving hole, the receiving disc 501 is arranged right below the tail end of the sieving cylinder 4A, an eccentric wheel disc 503 is connected below the receiving disc 501, a second transmission mechanism 504 is connected with the eccentric wheel disc 503, the second transmission mechanism 504 drives the eccentric wheel disc 503 to rotate, when the eccentric wheel disc 503 rotates, collecting discs on the receiving disc 501 are sequentially and one by one replaced below the sieving cylinder 4A, the rotating interval of the eccentric wheel disc 503 is controlled, so that the collecting amount in each collecting pipe 502 is controlled to be equal, due to the relative motion between the first sieving disc 403 and the second sieving disc 402, in two adjacent collecting pipes 502, only liquid water obtained by filtering is arranged in the collecting pipe 502, soil obtained by sieving is obtained by the other collecting pipe 502, the sampling cylinder 3A is provided with a primary treatment mechanism, the preliminary treatment mechanism comprises a first connecting disc 307 and a second connecting disc 306, the upper part of the first connecting disc 307 is connected with a motor, the second connecting disc 306 is arranged below the first connecting disc 307, the gravity center of the second connecting disc 306 is provided with a through hole, a sampling rod 303 passes through the through hole to be connected with the motor above the first connecting disc 307, the outer edge of the second connecting disc 306 is provided with a treatment hole, the lower part of the treatment hole is connected with a sieving cylinder 4A through a hose, a scraping plate is arranged between the first connecting disc 307 and the second connecting disc 306 and fixedly connected with the sampling rod 303, a plurality of arc-shaped grooves 307a are arranged above the first connecting disc 307, the first connecting disc 307 is connected with the first connecting disc 307 through a plurality of support columns 308, the lower ends of the support columns 308 are fixedly connected with the second connecting disc 306, the upper ends of the support columns 308 pass through the arc-shaped grooves 307a of the first connecting disc 307, and the upper ends of the support columns 308 are, any of the struts 308 are connected by a third drive mechanism.

The screening cylinder 4A is also internally provided with an inner container, and the inner container is internally provided with a controller, a configuration manager, a plurality of data processors, a memory and a storage battery; the data acquisition interfaces are respectively connected with the data processors in the liner, the data processors are connected with the configuration manager, and the configuration manager, the storage battery and the data output interface are all connected with the controller.

Example two

As shown in fig. 1 to 8, the 5G technology-based big data acquisition device of the present invention includes a support base 1, a driving assembly 2 and an acquisition assembly are disposed above the support base 1;

the driving assembly 2 comprises a first driving assembly, the first driving assembly is connected with the acquisition assembly, the first driving assembly comprises a first transmission mechanism, a first mounting plate 201 and a second mounting plate 202 which are parallel to each other, the first mounting plate 201 and the second mounting plate 202 are mounted on the left side and the right side of the first mounting plate 201 above the supporting seat 1, a plurality of mounting columns 203 are mounted on the left side and the right side of the first mounting plate 201, the second mounting plate 202 is provided with a longitudinal slide rail 209, a first slide block 208 is connected in the longitudinal slide rail 209 in a sliding manner, a transverse slide rail 206 is arranged between the first mounting plate 201 and the second mounting plate 202, the transverse slide rail 206 is connected with a second slide block 207 in a sliding manner, the second slide block 207 is connected with the first slide block 208, the second slide block is connected with the first transmission mechanism, the first, meanwhile, the first sliding block 208 slides relative to the longitudinal sliding rail 209, and one end of the first sliding block 208, which is far away from the second sliding block 207, is connected with the acquisition assembly;

gather the assembly including sampling component 3 and rather than the screening part of being connected, sampling component 3 includes sampler barrel 3A, the inside sample rod 303 that is equipped with of sampler barrel 3A, the outside cover of sample rod 303 has protective housing 301, be equipped with antiseized thorn 301a on the protective housing, prevent that soil from gluing on the protective housing, the upper end of sample rod 303 is connected with and is used for driving sample rod 303 pivoted motor, the motor passes through connecting rod 210 with second slider 207 and is connected, the bottom fixedly connected with sample drill bit 302 of sample rod 303.

The sampling rod 303 above the collection assembly is operated to reciprocate up and down through the driving assembly 2, the first transmission mechanism drives the second sliding block 207 to slide relative to the transverse sliding rail 206, the first sliding block 208 is connected with the second sliding block 207 in a sliding manner, the transverse sliding rail 206 is only connected with the second sliding block 207, the first sliding block 208 slides up and down along the longitudinal sliding rail 209 simultaneously, the first sliding block 208 is connected with a motor connected with the sampling rod 303 through a connecting rod 210, the sampling rod 303 reciprocates up and down, when the first sliding block 208 moves to the bottom end of the longitudinal sliding rail 209, the sampling drill 302 drills soil downwards to the limit depth, and the sampling rod 303 is upwards provided with a spiral hinge blade 304 from the connection part with the sampling drill 302. When the sampling rod 303 reciprocates up and down, the helical twisting blade 304 brings the soil drilled by the sampling drill 302 into the sampling cylinder 3A.

The first transmission mechanism comprises three transmission wheels 204, the three transmission wheels 204 are arranged on the first mounting plate 201 through mounting posts 203 on the first mounting plate 201, the three transmission wheels 204 form an acute triangle, the three transmission wheels 204 are in transmission connection through a belt 205, the belt 205 is connected with the second sliding block 207 through a cross rod 212, and the belt 205 drives the second sliding block 207 to move synchronously.

Because the three driving wheels 204 form an acute triangle, the movement direction of the belt 205 driving the second sliding rail is an oblique line instead of a horizontal line, and can be divided into movement in the horizontal direction and movement in the vertical direction, that is, the movement of the first sliding block 208 in the vertical direction and the movement of the second sliding block 207 in the horizontal direction, and the up-and-down movement of the sampling rod 303 is realized, the time required by the up-and-down reciprocating movement of the sampling rod 303 is also limited, an anti-skid wheel 211 is further arranged between the three driving wheels 204, and the anti-skid wheel 211 is also in synchronous transmission connection with the belt 205.

When the belt 205 drives three drive wheel 204 and rotates, take place to slide easily, it can reduce the emergence of this kind of condition to set up anti-skidding wheel 211, prevent the accident at sampling process, the screening part includes first screening portion 4 and second screening portion 5, first screening portion 4 includes screening section of thick bamboo 4A and the first screening subassembly that two run through, first screening subassembly is established inside screening section of thick bamboo 4A, screening section of thick bamboo 4A one end is connected with sampling tube 3A, screening section of thick bamboo 4A's the other end is connected with second screening portion 5, and screening section of thick bamboo 4A inclines down towards second screening portion 5 from the junction with sampling tube 3A, utilize first screening portion 4 and second screening portion 5 to carry out batching, the categorised collection to the soil that the sampling obtained.

The first screening assembly comprises a first screening disc 403 and a second screening disc 402, the first screening disc 403 is arranged above the second screening disc 402, sampled soil enters the screening cylinder 4A through the sampling rod 303, the sampled soil firstly passes through the first screening disc 403, the first screening disc 403 is fixedly connected with the inner wall of the first screening disc 403, the second screening disc 402 is arranged in the screening cylinder 4A through a connecting shaft 401, the connecting shaft 401 penetrates through the first screening disc 403, the connecting shaft 401 is movably connected with the first screening disc 403, the switching shaft is fixedly connected with the second screening disc 402, the first screening holes 404 are formed in the first screening disc 403 and the plurality of second screening discs 402, the first screening holes 404 in the first screening disc 403 and the first screening holes 404 in the second screening disc 402 are on the same axis, the second screening disc 402 is further provided with second screening holes 405, and the surface of the second screening holes 405 is covered with a water filtering net, the second screening holes 405 are smaller than the first screening holes 404, and the connecting shaft 401 is connected with a driving motor.

The soil obtained by sampling enters the screening cylinder 4A through the sampling cylinder, because the screening cylinder 4A inclines downwards from the joint with the sampling cylinder 3A towards the second screening part 5, the soil can move downwards under the action of the gravity of the soil, the soil firstly passes through the first screening holes 404 on the first screening disc 403, the first screening holes 404 limit the passing of larger soil, the driving motor drives the connecting shaft 401 to rotate, the second screening disc 402 is connected with the connecting shaft 401, the second screening disc 402 moves synchronously along with the connecting shaft 401, when the first screening holes 404 on the second screening disc 402 are aligned with the first screening holes 404 on the first screening disc 403, the soil above the first screening disc 403 enters the second screening part 5 through the second screening disc 402, the soil moisture content of the soil is high, and the first screening holes 404 are not aligned with the first screening holes 404 on the first screening disc 403, only the soil passes through the second screening holes 405 into the second screening portion 5.

Preferably, an external thread is arranged on the outer surface of the connecting shaft 401, an internal thread hole is formed in the center of the first screening plate 403, and the external thread on the outer surface of the connecting shaft 401 is in threaded fit with the internal thread hole on the first screening plate 403.

The connecting shaft 401 is in threaded fit with the first screening disc 403, when the driving motor controls the connecting shaft 401 to rotate forward, the second threaded disc moves towards the first threaded disc under the action of the threads, at the moment, soil between the first screening disc 403 and the second screening disc 402 is squeezed, most of water is squeezed out, and the squeezed water enters the second screening part 5 through the second screening holes 405.

The second sieving part 5 comprises a receiving disc 501, a plurality of receiving holes are formed in the upper portion of the receiving disc 501, a collecting pipe 502 is placed in each receiving hole, the receiving disc 501 is arranged right below the tail end of the sieving cylinder 4A, an eccentric wheel disc 503 is connected below the receiving disc 501, a second transmission mechanism 504 is connected with the eccentric wheel disc 503, the second transmission mechanism 504 drives the eccentric wheel disc 503 to rotate, when the eccentric wheel disc 503 rotates, collecting discs on the receiving disc 501 are sequentially and one by one replaced below the sieving cylinder 4A, the rotating interval of the eccentric wheel disc 503 is controlled, so that the collecting amount in each collecting pipe 502 is controlled to be equal, due to the relative motion between the first sieving disc 403 and the second sieving disc 402, in two adjacent collecting pipes 502, only liquid water obtained by filtering is arranged in the collecting pipe 502, soil obtained by sieving is obtained by the other collecting pipe 502, the sampling cylinder 3A is provided with a primary treatment mechanism, the preliminary treatment mechanism comprises a first connecting disc 307 and a second connecting disc 306, the upper part of the first connecting disc 307 is connected with a motor, the second connecting disc 306 is arranged below the first connecting disc 307, the gravity center of the second connecting disc 306 is provided with a through hole, a sampling rod 303 passes through the through hole to be connected with the motor above the first connecting disc 307, the outer edge of the second connecting disc 306 is provided with a treatment hole, the lower part of the treatment hole is connected with a sieving cylinder 4A through a hose, a scraping plate is arranged between the first connecting disc 307 and the second connecting disc 306 and fixedly connected with the sampling rod 303, a plurality of arc-shaped grooves 307a are arranged above the first connecting disc 307, the first connecting disc 307 is connected with the first connecting disc 307 through a plurality of support columns 308, the lower ends of the support columns 308 are fixedly connected with the second connecting disc 306, the upper ends of the support columns 308 pass through the arc-shaped grooves 307a of the first connecting disc 307, and the upper ends of the support columns 308 are, any of the struts 308 are connected by a third drive mechanism.

When the sampling drill 302 drills soil, the soil brought into the sampling cylinder 3A by the spiral twisting blade 304 may contain some large stones and may also contain large soil blocks, the large stones and the large soil blocks are removed by the primary processing mechanism, a scraper is arranged between the first connecting disc 307 and the second connecting disc 306, the scraper rotates synchronously with the sampling rod 303, the first connecting disc 307 and the second connecting disc 306 are connected by the support column 308, the third transmission mechanism drives any support column 308 to slide in the arc-shaped groove 307a, the second connecting disc 306 is fixedly connected with the support column 308, the second connecting disc 306 rotates back and forth along with the support column 308 in the arc-shaped groove 307a, the angle of each rotation is acute, under the relative motion of the second connecting disc 306 and the scraper, the soil on the second connecting disc 306 is subjected to primary processing, and the large soil blocks are refined, the third transmission mechanism comprises a first transmission shaft 309, one end of the first transmission shaft 309 is fixedly connected with the support column 308, the upper end of the first transmission shaft 309 is connected with a second transmission shaft 310, the other end of the second transmission shaft 310 is fixedly connected with a rotating shaft, the first transmission shaft 309 and the second transmission shaft 310 form an L shape, the tail end of the sieving cylinder 4A is provided with a funnel 406, and the lower part of the funnel 406 is right opposite to the pipe opening of the collecting pipe 502.

The soil or liquid water obtained after screening is accurately conveyed into the collecting pipe 502 through the funnel 406, an inner container is further arranged in the screening cylinder 4A, and a controller, a configuration manager, a plurality of data processors, a memory and a storage battery are arranged in the inner container; the data acquisition interfaces are respectively connected with a plurality of data processors in the liner, the data processors are connected with the configuration manager, and the configuration manager, the storage battery and the data output interface are all connected with the controller.

In addition, the invention also provides a using method of the 5G technology-based big data acquisition equipment, which comprises the following steps:

step one, structure installation; the driving assembly 2 and the collecting assembly are sequentially assembled for installation, the driving assembly 2 comprises a first transmission mechanism, a first mounting plate 201 and a second mounting plate 202 which are parallel to each other, the collecting assembly comprises a sampling cylinder 3A, a sampling rod 303 arranged in the sampling cylinder 3A, a primary processing mechanism, a first screening part 4 and a second screening part are arranged in the sampling cylinder 3A, and a sampling drill 302 is arranged at the bottom end of the sampling rod 303;

step two, setting parameters; through preliminary detection, judging the area of soil to be detected and the depth of the soil to be detected, selecting proper heights of the first mounting plate 201 and the second mounting plate 202, mounting the acquisition equipment on the ground, determining the depth of the sampling drill bit 302 capable of moving to the ground through the vertical distance from the driving wheel 204 arranged at the uppermost part to the driving wheel 204 arranged at the lowermost part, and setting the moving speed of the belt 205, the rotating speed of the sampling rod 303 and the rotating speed of the eccentric wheel disc 503;

step three, after the parameters are set, starting the collecting equipment until the number of the collected collecting pipes 502 meets the requirements, closing the equipment, and numbering and sequencing all the collecting pipes 502 in sequence, wherein the sampling rod 303, the sampling drill bit 302, the screening cylinder 4A and the funnel 406 all need to be cleaned for the next use;

acquiring data extraction parameters, namely data screening conditions and data deformation configuration, selecting root nodes according to the data extraction parameters, determining a data table dependency relationship tree, and constructing a data table extraction sequence by using the data table dependency relationship tree; generating an extraction script according to the formed collection pipe 502 sequence extraction sequence and the data extraction parameters;

and fifthly, extracting data by using the extraction script, detecting soil properties to generate a data file, importing the data file into a target database, comparing and searching the data of the target database and a data comparison module, analyzing the data by a data analysis module, analyzing the finally obtained data to generate an analysis line graph, and obtaining a final visual analysis structure.

The foregoing is merely an example of the present invention, and common general knowledge in the field of known specific structures and characteristics is not described herein in any greater extent than that known in the art at the time of filing or priority date of the present application, so that those skilled in the art can now appreciate that all of the above-described techniques in this field and have the ability to apply routine experimentation before this date can be combined with one or more of the present application to produce a new embodiment, and that no one of ordinary skill in the art would recognize that such techniques or methods would not be a hindrance to implementing the present application. It should be noted that, for those skilled in the art, without departing from the structure of the invention, several changes and modifications can be made, which should also be regarded as the protection scope of the invention, and these will not affect the effect of the invention and the practicability of the patent。

Claims (10)

1. The utility model provides an acquisition equipment based on 5G technique big data which characterized in that: the device comprises a supporting seat, wherein a driving assembly and an acquisition assembly are arranged above the supporting seat;

the driving assembly comprises a first driving component which is connected with the collection assembly, the first driving assembly comprises a first transmission mechanism, a first mounting plate and a second mounting plate which are parallel to each other, the first mounting plate and the second mounting plate are arranged above the supporting seat, a plurality of mounting columns are arranged at the left side and the right side of the first mounting plate, the second mounting plate is provided with a longitudinal slide rail, the longitudinal slide rail is connected with a first slide block in a sliding way, a transverse sliding rail is arranged between the first mounting plate and the second mounting plate and is connected with a second sliding block in a sliding way, the second sliding block is connected with the first sliding block, the second sliding block is connected with a first transmission mechanism, the first transmission mechanism drives the second sliding block to slide relative to the transverse sliding rail, meanwhile, the first sliding block slides relative to the longitudinal sliding rail, and one end of the first sliding block, which is far away from the second sliding block, is connected with the acquisition assembly;

gather the assembly including sample part and rather than the screening part of being connected, sample part includes the sampling tube, the inside sample rod that is equipped with of sampling tube, the upper end of sample rod is connected with and is used for the drive the sample rod pivoted motor, the motor with the second slider passes through the connecting rod and connects, the bottom fixedly connected with sample drill bit of sample rod.

2. The 5G technology big data-based acquisition device according to claim 1, characterized in that: the first transmission mechanism comprises three transmission wheels, the three transmission wheels are installed on the first installation plate through installation columns on the first installation plate, the three transmission wheels form an acute triangle, the three transmission wheels are connected through a belt in a transmission mode, the belt is connected with the second sliding block through a cross rod, and the belt drives the second sliding block to move synchronously.

3. The 5G technology big data-based acquisition device according to claim 2, characterized in that: and an anti-skid wheel is also arranged between the three driving wheels and is also in synchronous transmission connection with the belt.

4. The 5G technology big data-based acquisition device according to claim 3, characterized in that: the screening part includes first screening portion and second screening portion, first screening portion includes a screening section of thick bamboo and the first screening subassembly that two run through, first screening subassembly is established screening section of thick bamboo is inside, screening section of thick bamboo one end with the sampling tube is connected, the other end and the second screening portion of screening section of thick bamboo are connected, just screening section of thick bamboo from with the sampling tube junction orientation the downward sloping of second screening portion.

5. The 5G technology big data-based acquisition device according to claim 4, characterized in that: the first screening assembly comprises a first screening disc and a second screening disc, the first screening disc is arranged above the second screening disc, when sampled soil enters a screening cylinder through a sampling rod, the sampled soil firstly passes through the first screening disc, the first screening disc is fixedly connected with the inner wall of the first screening disc, the second screening disc is installed in the screening cylinder through a connecting shaft, the connecting shaft penetrates through the first screening disc, the connecting shaft is movably connected with the first screening disc, the switching shaft is fixedly connected with the second screening disc, first screening holes are formed in the first screening disc and a plurality of second screening discs, the first screening holes in the first screening disc and the second screening disc are located on the same axis, second screening holes are formed in the second screening disc, and a water filtering net covers the surface of the second screening holes, the size of the second screening hole is smaller than that of the first screening hole, and the connecting shaft is connected with a driving motor.

6. The 5G technology big data-based acquisition device according to claim 5, characterized in that: the connecting axle surface is equipped with one end external screw thread, open at first screening dish center has the internal thread hole, just the external screw thread of connecting axle surface with internal thread hole screw-thread fit on the first screening dish.

7. The 5G technology big data-based acquisition equipment according to claim 5 or 6, characterized in that: the second screening portion includes the storage tray, open the storage tray top has a plurality of holding holes, and the collecting pipe has all been placed to every holding hole, the storage tray is located under the end of screening section of thick bamboo, the below of storage tray is connected with eccentric rim plate, eccentric rim plate is connected with second drive mechanism, the drive of second drive mechanism eccentric rim plate rotates.

8. The 5G technology big data-based acquisition device according to claim 7, wherein: the sampling cylinder is provided with a primary treatment mechanism, the primary treatment mechanism comprises a first connecting disc and a second connecting disc, the upper part of the first connecting disc is connected with a motor, the second connecting disc is arranged below the first connecting disc, a through hole is arranged at the gravity center of the second connecting disc, the sampling rod penetrates through the through hole to be connected with the motor above the first connecting disc, a treatment hole is arranged on the outer edge of the second connecting disc, the lower part of the treatment hole is connected with the sieving cylinder through a hose, a scraper is arranged between the first connecting disc and the second connecting disc and is fixedly connected with the sampling rod, a plurality of arc-shaped grooves are arranged above the first connecting disc, the first connecting disc is connected with the first connecting disc through a plurality of support columns, the lower end of each support column is fixedly connected with the second connecting disc, and the upper end of each support column penetrates through the arc-shaped grooves of the first connecting disc, and the upper ends of the support columns are connected with the arc-shaped grooves in a sliding mode, and any support column is connected through a third transmission mechanism.

9. The 5G technology big data-based acquisition device according to claim 8, wherein: the third transmission mechanism comprises a first transmission shaft, one end of the first transmission shaft is fixedly connected with the support column, the upper end of the first transmission shaft is connected with a second transmission shaft, the other end of the second transmission shaft is fixedly connected with a rotating shaft, and the first transmission shaft and the second transmission shaft form an L shape.

10. The 5G technology big data-based acquisition device according to claim 9, wherein: the end of the screening cylinder is provided with a funnel, and the lower part of the funnel is right opposite to the pipe orifice of the collecting pipe.

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