CN113533697A - Regional detection device is used in soil pollution based on big data - Google Patents

Abstract

The invention discloses a soil pollution area detection device based on big data, belonging to the soil detection field, and comprising a mounting seat, wherein an equipment box is fixedly arranged at the upper end of the mounting seat, a pair of probe boxes is fixedly connected at the upper end of the mounting seat, the two probe boxes are respectively positioned at the left side and the right side of the equipment box, a soil detection control system is arranged in the equipment box, a plurality of pre-embedded probes are arranged in the probe boxes, the soil detection control system can analyze the data of the area by placing the pre-embedded probes in the soil area to be detected, and the pre-embedded probes are controlled to continuously detect the soil in the area, the accurate data result can be effectively obtained through big data analysis, the effectiveness of the detection device is improved, the actual data of soil pollution can be effectively obtained, and the real condition of the soil can be effectively reflected in time, improving the efficiency of soil protection.

Description

Regional detection device is used in soil pollution based on big data

Technical Field

The invention relates to the field of soil detection, in particular to a soil pollution area detection device based on big data.

Background

Soil pollutants can be broadly classified into two broad categories, inorganic pollutants and organic pollutants. The inorganic pollutants mainly comprise acid, alkali, heavy metal, salts, compounds of radioactive elements cesium and strontium, compounds containing arsenic, selenium and fluorine, and the like. The organic pollutants mainly comprise organic pesticides, phenols, cyanides, petroleum, synthetic detergents, 3, 4-benzopyrene, harmful microorganisms brought by municipal sewage, sludge and animal manure, and the like. When the soil contains excessive harmful substances and exceeds the self-cleaning capacity of the soil, the composition, the structure and the function of the soil are changed, the activity of microorganisms is inhibited, and the harmful substances or decomposition products thereof are gradually accumulated in the soil and are indirectly absorbed by the human body through the soil → plants → the human body or through the soil → water → the human body, so that the degree of harming the health of the human body is reached, namely the soil pollution.

Soil pollution monitoring is one of the important contents of environmental monitoring, and aims to find background values, monitor, forecast and control soil environmental quality. The preferential monitor of soil pollution should be a substance that has a significant impact on the health of the human population and on maintaining ecological balance. Elemental and inorganic contaminants such as mercury, cadmium, lead, arsenic, copper, aluminum, nickel, zinc, selenium, chromium, vanadium, manganese, sulfates, nitrates, halides, carbonates, and the like; petroleum, organophosphorus and organochlorine pesticides, polycyclic aromatic hydrocarbons, polychlorinated biphenyls, chloral and other biologically active substances; infectious bacteria and viruses introduced from the fecal waste and the domestic sewage, etc. The determination of the soil pollution components belongs to trace analysis and ultra trace analysis, and in addition to the particularity of the soil environment, the difference of the monitoring values by 10-20% is generally considered to be understandable. The soil pollution monitoring result has important significance for mastering the soil quality condition, implementing a soil pollution control prevention and control approach and quality management.

The existing soil pollution detection device can only detect partial soil, is limited to soil quality detection at the installation position, has large detection area limitation, cannot effectively obtain actual data of soil pollution, cannot timely and effectively display the soil environment, and reduces the efficiency of soil protection.

Disclosure of Invention

1. Technical problem to be solved

Aiming at the problems in the prior art, the invention aims to provide a soil pollution area detection device based on big data, which can make a soil detection control system analyze the data of an area by placing a plurality of pre-buried probes in the soil area to be detected, control the pre-buried probes to continuously detect the soil in the area, effectively obtain an accurate data result through big data analysis, improve the effectiveness of the detection device, effectively obtain actual data of soil pollution, timely and effectively reflect the real condition of the soil and improve the soil protection efficiency.

2. Technical scheme

In order to solve the above problems, the present invention adopts the following technical solutions.

A large-data-based soil pollution area detection device comprises a mounting seat, wherein an equipment box is fixedly mounted at the upper end of the mounting seat, a pair of probe boxes is fixedly connected to the upper end of the mounting seat, the two probe boxes are respectively positioned at the left side and the right side of the equipment box, a soil detection control system is arranged in the equipment box, a plurality of pre-buried probes are arranged in the probe boxes, the rear ends of the pre-buried probes are fixedly connected with a pipeline storage box, pipeline bundles are arranged in the pipeline storage box, and the inner ends of the pipeline bundles extend to the outer side of the pipeline storage box and are electrically connected with the soil detection control system;

the soil detection control system comprises a wireless data transceiver module, a soil data output module is connected to the input end of the wireless data transceiver module, a soil data analysis module is connected to the input end of the soil data output module, a soil data monitoring module is connected to the input end of the soil data analysis module, a soil detector control module is connected to the input end of the soil data monitoring module, the soil detector control module is electrically connected with a pre-buried probe through a wire, and a soil detection control platform is connected to the output end of the wireless data transceiver module. A plurality of pre-buried probes are placed in a soil area needing to be detected, the soil detection control system analyzes data of the area, the pre-buried probes are controlled to continuously detect soil of the area, accurate data results are effectively obtained through big data analysis, effectiveness of the detection device is improved, actual data of soil pollution are effectively obtained, real conditions of the soil can be timely and effectively reflected, and soil protection efficiency is improved.

Further, set up supplementary chamber in the pre-buried probe, be provided with supplementary probe that buries in the supplementary chamber, set up the cavity in the supplementary probe that buries, install the air bag in the cavity, a pair of pressure boost air cock of air bag internal end fixedly connected with, pressure boost air cock the inner extends to the supplementary probe outside of burying, be connected with electric control valve on the air bag, electric control valve passes through wire and soil detector control module electric connection. Generate the strength of spouting through aerifing the gasbag, make supplementary probe that buries produce explosive power, discharge from pre-buried probe, and the continuation removes in to soil, when needs further detect soil, effectively increase pre-buried probe's detection distance, improve the variety of testing data, be convenient for quick effectual pollution sources who detects out soil, and supplementary probe that buries can be when pre-buried probe differential damage, in time carry out the alternate supply to pre-buried probe, effectively guarantee soil detection's continuation and stability.

Furthermore, an auxiliary through hole communicated with the auxiliary cavity is formed in the outer end of the embedded probe, the auxiliary through hole is matched with the auxiliary soil-entering probe, and the outer end of the embedded probe is fixedly connected with a barrier film matched with the auxiliary through hole. The barrier film protects the auxiliary soil-penetrating probe in the embedded probe, the auxiliary soil-penetrating probe is effectively prevented from being corroded when the auxiliary soil-penetrating probe is not used, the service life of the auxiliary soil-penetrating probe is prolonged, and the effectiveness of later-stage work of the auxiliary soil-penetrating probe is effectively guaranteed.

Further, supplementary probe that buries has last seted up spiral hemisphere groove, supplementary probe outer end fixedly connected with triangle metal head that buries, the spout has all been seted up to the inner wall around the guide ball, fixedly connected with guide spring in the spout, guide spring outer end fixedly connected with and triangle metal head assorted guide ball. Through guide ball and spiral half spherical groove phase-match, when supplementary probe that buries passes supplementary through-hole, can produce the revolving force of removal, improve the explosive power in supplementary probe that buries gets into soil, the supplementary distance of probe that buries that increases removes in soil, and the triangle metal head can effectively break the barrier film, reduce the energy loss of supplementary probe that buries, carry out the direction guide to supplementary probe that buries after getting into soil, the removal distance of further supplementary probe that buries, the validity of supplementary probe detection data that buries is improved.

Furthermore, the outer end of the pipeline bundle extends into the embedded probe and is rotatably connected with the auxiliary soil-entering probe, and the inner lead of the pipeline bundle is electrically connected with the auxiliary soil-entering probe. The embedded probe and the auxiliary soil-penetrating probe are connected through the pipeline bundle, so that data of the embedded probe and the auxiliary soil-penetrating probe can be effectively transmitted to a soil detection control system through the pipeline bundle, convenience is brought to data acquisition of detection personnel, and the embedded probe and the auxiliary soil-penetrating probe provide effective electric energy so that the embedded probe and the auxiliary soil-penetrating probe can effectively work.

Furthermore, the lower end of the mounting seat is fixedly connected with a mounting foot, and the lower end of the mounting foot is triangular. The mounting foot of triangle-shaped can effectively insert in soil, improves the stability of mount pad, and the detector installation of being convenient for saves detector's physical power.

Further, equipment box upper end fixed connection signal receiving pole, the signal receiving pole passes through the wire and is connected with wireless data transceiver module electronic box, a plurality of gas probe that are located limit number receiving pole right side of equipment box upper end fixedly connected with, gas probe passes through wire and soil detector control module electric connection. The soil external air environment is detected through the gas probe, the soil detection control system is assisted to detect the soil environment in the area, the signal intensity of the wireless data transceiver module is improved through the signal receiving rod, and the signal transmission speed is improved.

Further, pipeline storage box outer end fixed connection protection casing, fixed mounting has miniature inductor in the protection casing. Through miniature inductor be convenient for the measurement personnel later stage carry out recycle to pre-buried probe and supplementary probe that buries, the current resource of rational utilization reduces the detection cost to effectively avoid remaining pre-buried probe and supplementary probe that buries to cause secondary pollution to soil.

Furthermore, the outside of the pipeline bundle is wrapped with a plastic sheath, and the outer end of the plastic sheath is coated with an anti-corrosion layer. The plastic sheath protects the pipe line bundle and the wires inside the pipe line bundle, effectively prevents the pipe line bundle from being damaged in soil, enables the embedded probe and the auxiliary soil-entering probe not to work normally, effectively prolongs the service life of the pipe line bundle, and improves the corrosion resistance of the pipe line bundle.

In addition, the invention also discloses a detection method of the soil pollution area detection device based on the big data, which comprises the following steps:

s1, mounting a mounting seat in a soil area needing to be detected by a detector in advance;

s2, embedding the embedded probes into soil at equal intervals according to the area size of the soil to be detected;

s3, detecting pollution data in the soil through the embedded probe, and conveying the pollution data to a soil data monitoring module;

s4, the soil data monitoring module transmits the data detected by the embedded probe to the soil data analysis module;

s5, analyzing the data of the embedded probes by a soil data analysis module, and transmitting the analyzed data to a soil data output module;

s6, the soil data output module transmits the analysis data to a soil detection control platform through the wireless data transceiver module;

s7, judging and evaluating the obtained analysis data by the soil detection control platform through big data analysis and comparison, and transmitting the data to detection personnel;

s8, controlling the soil detection control platform to send feedback data by a detector, and transmitting the data to the soil detector control module through the wireless data transceiver module;

and S9, controlling the embedded probe by the soil detector control module. Through installing detection device in waiting to detect the region of soil, carry out pre-buried probe pre-buried through testing personnel, data control through a plurality of pre-buried probes and soil detection control system, make testing personnel can effectively obtain this soil environment's true data, use big data to carry out contrastive analysis, thereby effectively acquire soil pollution's data, can in time effectually administer soil, effective separation pollution source, and can effectively realize long-time incessant detection, reduce testing personnel's intensity of labour, testing personnel's work efficiency is improved.

3. Advantageous effects

Compared with the prior art, the invention has the advantages that:

(1) this scheme makes soil detection control system carry out the analysis to this regional data through placing a plurality of pre-buried probes in the soil region that needs detected to control pre-buried probe and continuously detect this regional soil, effectively obtain accurate data result through big data analysis, improve detection device's validity, effectively obtain soil pollution's actual data, can in time effectually reflect the true condition of soil, improve soil protection's efficiency.

(2) Produce the strength of spouting through aerifing the gasbag, make supplementary probe that buries produce explosive power, discharge from pre-buried probe to the continuation removes in to soil, when needs further detect soil, effectively increases pre-buried probe's detection distance, improves the variety of detection data, is convenient for quick effectual pollution sources who detects out soil.

(3) The auxiliary soil-entering probe can timely supplement the embedded probe when the embedded probe is damaged due to the difference, and the continuity and the stability of soil detection are effectively guaranteed.

(4) The barrier film protects the auxiliary soil-penetrating probe in the embedded probe, the auxiliary soil-penetrating probe is effectively prevented from being corroded when the auxiliary soil-penetrating probe is not used, the service life of the auxiliary soil-penetrating probe is prolonged, and the effectiveness of later-stage work of the auxiliary soil-penetrating probe is effectively guaranteed.

(5) Through guide ball and spiral half spherical groove phase-match, when supplementary probe that buries passes supplementary through-hole, can produce the revolving force of removal, improve the explosive power in supplementary probe that buries gets into soil, the supplementary distance of probe that buries that increases removes in soil, and the triangle metal head can effectively break the barrier film, reduce the energy loss of supplementary probe that buries, carry out the direction guide to supplementary probe that buries after getting into soil, the removal distance of further supplementary probe that buries, the validity of supplementary probe detection data that buries is improved.

(6) The embedded probe and the auxiliary soil-penetrating probe are connected through the pipeline bundle, so that data of the embedded probe and the auxiliary soil-penetrating probe can be effectively transmitted to a soil detection control system through the pipeline bundle, convenience is brought to data acquisition of detection personnel, and the embedded probe and the auxiliary soil-penetrating probe provide effective electric energy so that the embedded probe and the auxiliary soil-penetrating probe can effectively work.

(7) The mounting foot of triangle-shaped can effectively insert in soil, improves the stability of mount pad, and the detector installation of being convenient for saves detector's physical power.

(8) The soil external air environment is detected through the gas probe, the soil detection control system is assisted to detect the soil environment in the area, the signal intensity of the wireless data transceiver module is improved through the signal receiving rod, and the signal transmission speed is improved.

(9) Through miniature inductor be convenient for the measurement personnel later stage carry out recycle to pre-buried probe and supplementary probe that buries, the current resource of rational utilization reduces the detection cost to effectively avoid remaining pre-buried probe and supplementary probe that buries to cause secondary pollution to soil.

(10) The plastic sheath protects the pipe line bundle and the wires inside the pipe line bundle, effectively prevents the pipe line bundle from being damaged in soil, enables the embedded probe and the auxiliary soil-entering probe not to work normally, effectively prolongs the service life of the pipe line bundle, and improves the corrosion resistance of the pipe line bundle.

(11) Through installing detection device in waiting to detect the region of soil, carry out pre-buried probe pre-buried through testing personnel, data control through a plurality of pre-buried probes and soil detection control system, make testing personnel can effectively obtain this soil environment's true data, use big data to carry out contrastive analysis, thereby effectively acquire soil pollution's data, can in time effectually administer soil, effective separation pollution source, and can effectively realize long-time incessant detection, reduce testing personnel's intensity of labour, testing personnel's work efficiency is improved.

Drawings

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

FIG. 2 is a schematic diagram of a soil detection control system according to the present invention;

FIG. 3 is a schematic view of a front cross-sectional structure of an embedded probe according to the present invention;

FIG. 4 is a schematic view of an axial structure of a cross section of an embedded probe according to the present invention;

FIG. 5 is a schematic diagram of the structure at A in FIG. 4 according to the present invention;

FIG. 6 is a schematic view of an axial measurement structure of an auxiliary soil penetration probe of the present invention;

FIG. 7 is a schematic structural diagram of the embedded probe and the auxiliary soil-penetrating probe of the invention during detection;

FIG. 8 is a schematic view of the flow structure of the soil detection control system of the present invention;

FIG. 9 is a schematic view of the flow structure of the detection method of the present invention.

The reference numbers in the figures illustrate:

the device comprises a mounting seat 1, a probe box 2, an equipment box 3, a gas probe 4, a pre-buried probe 5, a barrier film 501, an auxiliary through hole 502, a guide ball 503, a guide spring 504, a pipeline storage box 6, a pipeline bundle 601, an auxiliary soil penetration probe 7, a triangular metal head 701, a spiral hemispherical groove 702, an inflatable air bag 8 and a pressurization air nozzle 801.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention; it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments, and all other embodiments obtained by those skilled in the art without any inventive work are within the scope of the present invention.

In the description of the present invention, it should be noted that the terms "upper", "lower", "inner", "outer", "top/bottom", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" 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 otherwise explicitly specified or limited, the terms "mounted," "disposed," "sleeved/connected," "connected," and the like are to be construed broadly, e.g., "connected," which may be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example 1:

referring to fig. 1-9, a soil pollution area detection device based on big data comprises a mounting base 1, wherein an equipment box 3 is fixedly mounted at the upper end of the mounting base 1, a pair of probe boxes 2 is fixedly connected to the upper end of the mounting base 1, the two probe boxes 2 are respectively located on the left side and the right side of the equipment box 3, a soil detection control system is arranged in the equipment box 3, a plurality of embedded probes 5 are arranged in the probe boxes 2, a pipeline storage box 6 is fixedly connected to the rear ends of the embedded probes 5, a pipeline bundle 601 is arranged in the pipeline storage box 6, and the inner end of the pipeline bundle 601 extends to the outer side of the pipeline storage box 6 and is electrically connected with the soil detection control system; referring to fig. 2, the soil detection control system includes a wireless data transceiver module, an input end of the wireless data transceiver module is connected with a soil data output module, an input end of the soil data output module is connected with a soil data analysis module, an input end of the soil data analysis module is connected with a soil data monitoring module, an input end of the soil data monitoring module is connected with a soil detector control module, the soil detector control module is electrically connected with the embedded probe 5 through a wire, and an output end of the wireless data transceiver module is connected with a soil detection control platform. Through placing a plurality of pre-buried probes 5 in the soil region that needs to detect, make soil detection control system carry out the analysis to this regional data to control pre-buried probe 5 and continuously detect this regional soil, effectively obtain accurate data result through big data analysis, improve detection device's validity, effectively obtain soil pollution's actual data, can in time effectual reflect the true condition of soil, improve soil protection's efficiency.

Referring to fig. 3 and 4, an auxiliary cavity is formed in the embedded probe 5, an auxiliary soil-entering probe 7 is arranged in the auxiliary cavity, a cavity is formed in the auxiliary soil-entering probe 7, an inflatable air bag 8 is installed in the cavity, a pair of pressure-increasing air nozzles 801 is fixedly connected to the inner end of the inflatable air bag 8, the inner end of the pressure-increasing air nozzles 801 extends to the outer side of the auxiliary soil-entering probe 7, and an electric control valve is connected to the inflatable air bag 8 and electrically connected with a soil detector control module through a wire. Generate the strength of spouting through aerifing gasbag 8, make supplementary probe 7 that buries produce explosive power, discharge from pre-buried probe 5, and the continuation removes in to soil, when needs further detect soil, effectively increase pre-buried probe 5's detection distance, improve the variety of detection data, be convenient for quick effectual pollution sources who detects out soil, and supplementary probe 7 that buries can be when pre-buried probe 5 is bad life damages, in time carry out the replacement to pre-buried probe 5, effectively guarantee soil detection's continuation and stability.

Referring to fig. 4, the outer end of the embedded probe 5 is provided with an auxiliary through hole 502 communicated with the auxiliary cavity, the auxiliary through hole 502 is matched with the auxiliary soil-entering probe 7, and the outer end of the embedded probe 5 is fixedly connected with a barrier film 501 matched with the auxiliary through hole 502. The barrier film 501 protects the auxiliary soil-penetrating probe 7 in the embedded probe 5, effectively prevents the auxiliary soil-penetrating probe 7 from being corroded when the auxiliary soil-penetrating probe 7 is not used, prolongs the service life of the auxiliary soil-penetrating probe 7, and effectively ensures the effectiveness of later-stage work of the auxiliary soil-penetrating probe 7.

Referring to fig. 4-6, the auxiliary soil-entering probe 7 is provided with a spiral hemispherical groove 702, the outer end of the auxiliary soil-entering probe 7 is fixedly connected with a triangular metal head 701, the front and rear inner walls of the guide ball 503 are provided with sliding grooves, the inner of the sliding grooves is fixedly connected with a guide spring 504, and the outer end of the guide spring 504 is fixedly connected with a guide ball 503 matched with the triangular metal head 701. Through the cooperation of guide ball 503 and spiral hemisphere groove 702, when supplementary probe 7 that buries passes supplementary through-hole 502, can produce the revolving force of removal, improve the explosive force of supplementary probe 7 that buries in the soil, the distance that supplementary probe 7 that buries removed in the soil is increased, and triangle metal head 701 can effectively break barrier film 501, reduce the energy loss of supplementary probe 7 that buries, carry out the direction guide to supplementary probe 7 that buries after getting into the soil, further increase the moving distance of supplementary probe 7 that buries, the validity of supplementary probe 7 that buries detection data improves.

Referring to fig. 3, the outer end of the pipe bundle 601 extends into the embedded probe 5 and is rotatably connected to the auxiliary soil-penetrating probe 7, and the inner lead of the pipe bundle 601 is electrically connected to the auxiliary soil-penetrating probe 7. The embedded probe 5 and the auxiliary soil-penetrating probe 7 are connected through the pipeline bundle 601, so that data of the embedded probe 5 and the auxiliary soil-penetrating probe 7 can be effectively transmitted to a soil detection control system through the pipeline bundle 601, data acquisition of detection personnel is facilitated, and the embedded probe 5 and the auxiliary soil-penetrating probe 7 provide effective electric energy so that the embedded probe can effectively work.

Referring to fig. 1, the lower end of the mounting base 1 is fixedly connected with a mounting leg, and the lower end of the mounting leg is triangular. The mounting foot of triangle-shaped can effectively insert in soil, improves the stability of mount pad 1, and the detector of being convenient for installs, saves detector's physical power.

Referring to fig. 1, the upper end of the equipment box 3 is fixedly connected with a signal receiving rod, the signal receiving rod is connected with the wireless data receiving and transmitting module electric box through a wire, the upper end of the equipment box 3 is fixedly connected with a plurality of gas probes 4 positioned on the right side of the signal receiving rod, and the gas probes 4 are electrically connected with the soil detector control module through wires. The soil external air environment is detected through the gas probe 4, the soil detection control system is assisted to detect the soil environment in the area, the signal intensity of the wireless data transceiver module is improved through the signal receiving rod, and the signal transmission speed is improved.

Referring to fig. 1, the outer end of the pipeline storage box 6 is fixedly connected to a shield, and a micro-sensor is fixedly installed in the shield. Be convenient for the measurement personnel later stage through miniature inductor and carry out recycle to pre-buried probe 5 and supplementary probe 7 that buries, the current resource of rational utilization reduces the detection cost to effectively avoid remaining pre-buried probe 5 and supplementary probe 7 that buries to cause secondary pollution to soil.

Referring to fig. 1, the outer side of the pipe bundle 601 is wrapped with a plastic sheath, and the outer end of the plastic sheath is coated with an anti-corrosion layer. The plastic sheath protects the pipe harness 601 and the internal conducting wires of the pipe harness 601, effectively prevents the pipe harness 601 from being damaged in soil, enables the embedded probe 5 and the auxiliary soil-entering probe 7 not to work normally, effectively prolongs the service life of the pipe harness 601, and improves the corrosion resistance of the pipe harness 601.

Referring to fig. 1-9, the method of use: a detector places the mounting base 1 on soil to be detected, inserts mounting feet into the soil and stabilizes the mounting base 1; selecting a proper interval according to the size of the soil area, and embedding the embedded probe 5 into the soil; the gas probe 4 detects air and the embedded probe 5 detects pollution data in soil and transmits the pollution data to the soil data monitoring module, the soil data monitoring module transmits the detected data to the soil data analysis module, the soil data analysis module analyzes the data and transmits the analyzed data to the soil data output module, the soil data output module transmits the analyzed data to the soil detection control platform through the wireless data transceiver module, the soil detection control platform judges and evaluates the obtained analyzed data through big data analysis and comparison and transmits the data to a detector, the detector controls the soil detection control platform to send feedback data, and the data are transmitted to the soil detector control module through the wireless data transceiver module; when the auxiliary soil-entering probe 7 is needed to be used, the soil detector control module opens an electric control valve on the pressurization air nozzle 801, so that gas in the inflatable air bag 8 is quickly ejected and is blocked by the inner wall of the embedded probe 5, the auxiliary soil-entering probe 7 is flushed out of an auxiliary cavity of the embedded probe 5, the triangular metal head 701 flushes the barrier film 501, the spiral hemispherical groove 702 is acted by the guide ball 503 to enable the auxiliary soil-entering probe 7 to rotate, the auxiliary soil-entering probe 7 enters the soil in a rotary mode, the detection range is enlarged, and detection data are continuously transmitted through the pipeline bundle 601; when the embedded probe 5 needs to be recovered, a detector searches nearby the embedded probe 5 through the inductor receiving end, and when the embedded probe 5 is close to the inductor receiving end, the miniature inductor sends out a signal, so that the detector can effectively acquire the position of the embedded probe 5, and the embedded probe 5 and the auxiliary soil-penetrating probe 7 are recovered. Through placing a plurality of pre-buried probes 5 in the soil region that needs to detect, make soil detection control system carry out the analysis to this regional data to control pre-buried probe 5 and continuously detect this regional soil, effectively obtain accurate data result through big data analysis, improve detection device's validity, effectively obtain soil pollution's actual data, can in time effectual reflect the true condition of soil, improve soil protection's efficiency.

Example 2:

referring to fig. 1 to 9, wherein the same or corresponding components as those in embodiment 1 are designated by the same reference numerals as those in embodiment 1, only the points different from embodiment 1 will be described below for the sake of convenience. This example 2 differs from example 1 in that: referring to fig. 9, a detection method of a soil pollution area detection device based on big data includes the following steps:

s1, mounting a mounting seat 1 in advance to a soil area needing to be detected by a detector;

s2, pre-burying the pre-buried probes 5 into the soil at equal intervals according to the area size of the soil to be detected;

s3, detecting pollution data in the soil through the embedded probe 5, and conveying the pollution data to a soil data monitoring module;

s4, the soil data monitoring module transmits the data detected by the embedded probe 5 to a soil data analysis module;

s5, analyzing the data of the embedded probes 5 by a soil data analysis module, and transmitting the analyzed data to a soil data output module;

s6, the soil data output module transmits the analysis data to a soil detection control platform through the wireless data transceiver module;

s7, judging and evaluating the obtained analysis data by the soil detection control platform through big data analysis and comparison, and transmitting the data to detection personnel;

s8, controlling the soil detection control platform to send feedback data by a detector, and transmitting the data to the soil detector control module through the wireless data transceiver module;

and S9, the soil detector control module controls the embedded probe 5 to control. Through installing detection device in waiting to detect the region of soil, carry out pre-buried probe 5 through measurement personnel pre-buried, data control through a plurality of pre-buried probes 5 and soil detection control system, make measurement personnel can effectively obtain this soil environment's true data, use big data to carry out contrastive analysis, thereby effectively acquire soil pollution's data, can in time effectually administer soil, effective separation pollution sources, and can effectively realize long-time incessant detection, reduce measurement personnel's intensity of labour, measurement personnel's work efficiency is improved.

The foregoing is only a preferred embodiment of the present invention; the scope of the invention is not limited thereto. Any person skilled in the art should be able to cover the technical scope of the present invention by equivalent or modified solutions and modifications within the technical scope of the present invention.

Claims (10)

1. The utility model provides a soil pollution uses regional detection device based on big data, includes mount pad (1), its characterized in that: an equipment box (3) is fixedly mounted at the upper end of the mounting seat (1), a pair of probe boxes (2) is fixedly connected to the upper end of the mounting seat (1), the two probe boxes (2) are respectively positioned at the left side and the right side of the equipment box (3), a soil detection control system is arranged in the equipment box (3), a plurality of pre-buried probes (5) are arranged in the probe boxes (2), the rear ends of the pre-buried probes (5) are fixedly connected with a pipeline storage box (6), a pipeline bundle (601) is arranged in the pipeline storage box (6), and the inner end of the pipeline bundle (601) extends to the outer side of the pipeline storage box (6) and is electrically connected with the soil detection control system;

the soil detection control system comprises a wireless data transceiver module, a soil data output module is connected to the input end of the wireless data transceiver module, a soil data analysis module is connected to the input end of the soil data output module, a soil data monitoring module is connected to the input end of the soil data analysis module, a soil detector control module is connected to the input end of the soil data monitoring module, the soil detector control module is electrically connected with a pre-buried probe (5) through a wire, and a soil detection control platform is connected to the output end of the wireless data transceiver module.

2. The big data-based area detection device for soil pollution according to claim 1, wherein: set up supplementary chamber in pre-buried probe (5), be provided with supplementary buried probe (7) in the supplementary chamber, supplementary buried probe (7) has seted up the cavity in, install in the cavity and aerify gasbag (8), aerify a pair of pressure boost air cock (801) of gasbag (8) inner fixedly connected with, pressure boost air cock (801) the inner extends to supplementary buried probe (7) outside, it is connected with electric control valve on gasbag (8) to aerify, electric control valve passes through wire and soil detector control module electric connection.

3. The big data-based area detection device for soil pollution according to claim 2, wherein: the embedded probe is characterized in that an auxiliary through hole (502) communicated with the auxiliary cavity is formed in the outer end of the embedded probe (5), the auxiliary through hole (502) is matched with the auxiliary soil-penetrating probe (7), and the outer end of the embedded probe (5) is fixedly connected with a barrier film (501) matched with the auxiliary through hole (502).

4. The big data-based area detection device for soil pollution according to claim 3, wherein: the utility model discloses a soil sample detection device, including supplementary probe (7) that buries, supplementary probe (7) that buries have been seted up on the probe (7) spiral hemisphere groove (702), supplementary probe (7) outer end fixedly connected with triangle metal head (701) that buries, the spout has all been seted up to inner wall around guide ball (503), fixedly connected with guide spring (504) in the spout, guide spring (504) outer end fixedly connected with and triangle metal head (701) assorted guide ball (503).

5. The big data-based area detection device for soil pollution according to claim 2, wherein: the outer end of the pipeline bundle (601) extends into the embedded probe (5) and is rotatably connected with the auxiliary soil-penetrating probe (7), and a lead in the pipeline bundle (601) is electrically connected with the auxiliary soil-penetrating probe (7).

6. The big data-based area detection device for soil pollution according to claim 1, wherein: the lower end of the mounting seat (1) is fixedly connected with a mounting foot, and the lower end of the mounting foot is triangular.

7. The big data-based area detection device for soil pollution according to claim 1, wherein: the utility model discloses a soil detector control module, including equipment box (3), signal receiving pole, gas probe (4) on equipment box (3) upper end fixedly connected with signal receiving pole, the signal receiving pole passes through the wire and is connected with wireless data transceiver module electronic box, a plurality of gas probe (4) that are located limit number receiving pole right side of equipment box (3) upper end fixedly connected with, gas probe (4) pass through wire and soil detector control module electric connection.

8. The big data-based area detection device for soil pollution according to claim 1, wherein: the outer end of the pipeline storage box (6) is fixedly connected with the protective cover, and a miniature inductor is fixedly arranged in the protective cover.

9. The big data-based area detection device for soil pollution according to claim 1, wherein: the outer side of the pipeline bundle (601) is wrapped with a plastic sheath, and the outer end of the plastic sheath is coated with an anti-corrosion layer.

10. The detection method of the soil pollution area detection device based on big data according to claim 1, characterized in that: the method comprises the following steps:

s1, mounting a mounting seat (1) in advance to a soil area needing to be detected by a detector;

s2, pre-burying the pre-buried probes (5) into the soil at equal intervals according to the area size of the soil to be detected;

s3, detecting pollution data in the soil through the embedded probe (5), and conveying the pollution data to a soil data monitoring module;

s4, the soil data monitoring module transmits the data detected by the embedded probe (5) to a soil data analysis module;

s5, analyzing the data of the embedded probes (5) by a soil data analysis module, and transmitting the analyzed data to a soil data output module;

s6, the soil data output module transmits the analysis data to a soil detection control platform through the wireless data transceiver module;

s7, judging and evaluating the obtained analysis data by the soil detection control platform through big data analysis and comparison, and transmitting the data to detection personnel;

s8, controlling the soil detection control platform to send feedback data by a detector, and transmitting the data to the soil detector control module through the wireless data transceiver module;

and S9, the soil detector control module controls the embedded probe (5) to control.

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