JP7015427B1 - Intelligent collection and analysis equipment for integrated collection and analysis of groundwater deliquescent - Google Patents

Abstract

The present invention discloses an intelligent collection and analysis device for integrated collection and analysis of underground water deliquescent, a collection tub, a protective net located at the top of the collection tub, a rotation mechanism and rotation located at the top of the protective net. A set of sampling pipes is provided on one side of the inner wall of the upper tub body, including a stirring mechanism connected to the lower part of the mechanism, and a perturbation pump fixed to the inner wall of the upper tub body is provided in the center of the sampling pipes. A filtration component is installed at the top of the collection tub, a liquid level sensor is installed in the center of one side of the inner wall of the upper tub body, and the liquid level sensor is connected to the controller at the top of the side wall of the upper tub body. The controller is electrically connected to the peristaltic pump via an electromagnetic relay, and a water metal detector is provided at the bottom of the upper tub body. The device of the present invention has a rational structure, is convenient to operate, can automatically collect groundwater dehydrated liquid, and automatically triggers collection via a liquid level sensor to control the collection amount and collection speed. It greatly improves the convenience of the device without the need to record and manually start it. [Selection diagram] Fig. 2

Description

The present invention belongs to the field of technology for analyzing and measuring groundwater dewatering, and specifically relates to an intelligent collection and analysis device for integrated collection and analysis of groundwater dewatering.

Groundwater leaching is a process in which some components of the soil surface layer enter the water and are removed together with the water by dissolving, hydrating, hydrolyzing, carbonating, etc., and the soil gradually becomes leached as the leaching action progresses. Acidifies to. For example, in the upper part of a soil section in a humid area, long-term surface-to-down leaching of water causes leaching of soluble substances and fine soil particles in the upper soil layer, resulting in lighter soil color and coarser particles. , It becomes a soil layer (leached layer) with high acidity and low fertility. The leached layer is also called the A layer, and its defective condition can be improved by plowing, fertilizing, particularly applying organic fertilizer or clayey soil fertilizer.

However, in recent years, with the widespread production and use of chemical fertilizers, the loss of various nutrients in the soil has become more and more serious, and beneficial elements in the soil are vertically downward with water below the active layer of plant roots. Most seriously, most of the leached elements eventually enter the water environment, contaminating surface waters such as rivers, rivers and lakes. It is one of the sources of agricultural pollution and threatens the safety of drinking groundwater. Therefore, accurate collection and monitoring of groundwater deliquescent is very important for accurate analysis of soil nutrient balance, investigation of nutrient cycle process and environmental risk assessment.

Currently, the collection of groundwater effluents is generally carried out by implanting a soil leaching solution sampling device under the roots of soil crops and carrying the leaching solution of the research sample to the laboratory for detection.
Collection, transfer and long-term exposure to air will destroy the original state of existence and have a constant effect on the measurement of elemental leaching. Chinese patent CN2085799959U discloses an automatic monitoring device for agricultural soil leaching liquid including leaching trays, experimental bolts, sample bolts, water level sensors, launch pipes, intake pipes, water pumps and motors, facilitating automatic measurement of experiments and manual operation. Leachate can be collected without the need for monitoring. However, it can cause sampling errors for long-term sampling, and immediate monitoring of leached liquids and soil cannot be achieved.

In view of the above problems, the present invention submits an intelligent collection and analysis device for integrated collection and analysis of groundwater dewatering liquid.
The technical solution of the present invention is as follows.
Intelligent collection and analysis equipment for integrated collection and analysis of groundwater deliquescent is a collection tub, a protective net located at the top of the collection tub, a rotation mechanism located at the top of the protection net, and a lower part of the rotation mechanism. Including a stirring mechanism connected to
The collecting tub is divided into an upper tub main body and a lower tub main body, a set of sampling pipes is provided on one side of the inner wall of the upper tub main body, and a sway fixed to the inner wall of the upper tub main body at the center of the sampling pipe. A pump is provided, a filtering component is provided at the top of the collection tub, a threaded tub is fixedly connected to the center of the inside of the top tub body, and the top and bottom of the threaded tub are the top and bottom of the top tub body. Corresponding to the sealable connection,
The rotary mechanism is provided with a housing fixedly connected to the protective net, an annular gear plate rotatably connected to the inside of the housing, and a rotary motor located on one side of the bottom in the housing. A rack is provided on the inner wall of the gear plate, the first gear is meshed with the rack, the upper output end of the rotary motor is connected to the center of the first gear, and the sleeve rod is centered at the bottom of the annular gear plate. Is fixedly provided, the sleeve rod is configured by fitting an outer rod and an inner rod extending into the threaded tub, a drill bit is provided at the bottom of the inner rod, and both sides of the upper end of the inner rod. Is provided with a strip-shaped protrusion movably engaged with a chute provided on the inner wall of the outer rod, a male screw is provided on the central outer wall of the inner rod, and the male screw is provided on the inner wall of the threaded tub. The outer wall of the inner rod, which is meshed with the female screw and between the lower part of the male screw and the drill bit, and between the upper part of the male screw and the strip-shaped protrusion, has a smooth surface, and the bottom of the inner rod is a threaded tub. Extend from to the inside of the lower tub body,
The lower output end of the rotary motor is connected to a stirring mechanism for turning the soil in the protective net through the bottom of the housing, and the bottom of the lower tub body is provided with an opening for the drill bit to pass through. A collection plate is provided at the bottom of the lower tub body around the opening, an annular collection groove is provided at the outer end of the collection plate, and a gas pipeline is provided on one side of the inner wall of the upper tub body. ,
A liquid level sensor is provided in the center of one side of the inner wall of the upper tub body, the liquid level sensor is connected to a controller at the top of the side wall of the upper tub body, and the controller is electrically connected to the perturbation pump. A water metal detector is provided at the bottom of the upper tub body, and the water metal detector can be connected to a data collection system outside the collection tub to immediately monitor data such as the heavy metal content in the leaching solution. can.

As one aspect of the present application, the upper end of the sampling pipe is connected to a collecting bolt outside the collecting tub, and the lower end of the sampling pipe is located at the bottom of the upper tub body and is in contact with the perturbing pump of the sampling pipe. One part is a hose, the other part of the sampling pipe is a PE water supply pipe, and the filtration component includes a steel wire net located on the upper surface of the upper tub body, and one layer of quartz sand under the steel wire net. There are particles, a one-layer soft plastic filter net is provided below the quartz sand particles, and a hard plastic filter net is provided below the soft plastic filter net.
In this application, the leached solution is collected by a peristaltic pump and the filtration effect is enhanced by multiple filtration.

As one aspect of the present application, the annular gear plate includes an annular plate and a fixed plate located inside and fixedly connected to the annular plate, and the annular plate above the fixing plate is an inner top surface of the housing. A rack is provided on the inner wall of the annular plate below the fixing plate, which is rotatably connected to the annular groove provided in.
In the present application, the sleeve rod and the stirring mechanism are operated by rotating the annular gear plate by a set of rotary motors.
As one aspect of the present application, a limiting portion for stopping the strip-shaped protrusion is provided at the bottom of the outer rod, the upper half of the drill bit is a spiral steel plate, and the lower half of the drill bit is a diamond tip. ..
In the present application, the setting of the limiting portion prevents the inner rod from escaping from the outer rod because the moving distance is too long when moving with respect to the threaded tub, and the spiral steel plate transports the soil into the lower tub body. ..

As one aspect of the present application, the central portion of the upper surface of the second gear provided in the stirring mechanism is connected to the output end of the lower portion of the rotary motor, and is engaged and connected to both sides of the second gear. A set of driven gears is provided, and a driven gear is also provided at a position flush with the second gear symmetrically with respect to the sleeve rod with respect to the second gear, and the upper surface of the three sets of the driven gears is provided. The central part is rotatably connected to the bottom of the housing via a pair of connecting rods, respectively, 3
Gear crawlers are provided on the outside of the set of driven gears, and the three sets of driven gears are rotatably connected in synchronization with the rack provided on the inside of the gear crawlers, and are connected to the outside of the gear crawlers at equal distances. Bulldozer plate is provided.
In this application, the bulldozer plate is driven by a gear crawler to export a part of the soil in the protective net, and by exchanging the soil, the adverse effect on the leached liquid collection efficiency due to the decrease in soil leaching capacity is prevented. do.

As an improvement of this application, the upper part of the gas pipeline was connected to a dual-purpose fan outside the collection tub, and the bottom of the gas pipeline was sealed and fixed between the upper tub body and the lower tub body. Connected to a gas four-way valve, three sets of gas conduits are branched from the gas four-way valve, the outlet of the first gas conduit leads to the bottom of the upper tub body, and the outlet of the second gas conduit leads to the drill bit. , The outlet of the third gas pipeline leads to the collection groove.
In the present application, the first gas conduit cleans the inside of the upper tub body with hot steam, and the second gas conduit blows the soil on the spiral steel plate with a dual-purpose fan and drops it into the collection groove. The gas conduit of 3 is collected by blowing soil with a dual-purpose fan.

As one aspect of the above improvement, the collection plate is inclined downward from the center toward the periphery, an annular groove is provided at the bottom of the collection plate, and the annular groove is provided together with an annular protrusion provided on the bottom surface of the lower tub body. A roller motor is provided on the side of the third gas conduit close to the collection plate to rotate the collection plate, and the lower output end of the roller motor is connected to the roller for rotating the collection plate, and the roller and the collection The friction of the plate causes the collection plate to rotate along the annular groove, which is convenient for soil collection in the third gas conduit.

The present invention has the following beneficial effects.
(1) The intelligent collection and analysis device for collecting and analyzing the groundwater dewatering solution of the present invention in an integrated manner has a rational structure, is convenient to operate, and can automatically collect the groundwater dewatering solution. , The liquid level sensor automatically triggers the collection to record the collection amount and collection speed, which greatly improves the convenience of the device without the need to start it manually.
(2) The intelligent collection and analysis device for integrated collection and analysis of the groundwater deliquescent of the present invention realizes the integration of sampling and detection by the water quality metal detector, and one trigger and stop of the peristaltic pump. As a cycle, the volume of the leached solution and the content of elements such as heavy metals in the leached solution are automatically recorded.
(3) In the intelligent collection and analysis device for integrated collection and analysis of the groundwater dewatering solution of the present invention, the built-in drill bit is made to collect the soil in a deep place through the sleeve rod by setting the rotation mechanism. Soil is sampled through a gas conduit to enable soil sample collection and detection delivery, and simultaneous detection of heavy metal content and soil humidity in the groundwater above and below the device helps to analyze leaching discipline.
(4) The intelligent collection and analysis device for integrated collection and analysis of the groundwater dewatering solution of the present invention agitates the upper leached soil by setting the stirring mechanism and exports a part of the soil in the protective net. , Further replacing the soil to prevent the impact of reduced soil leaching capacity on leaching solution collection efficiency, if the leaching solution is not collected for a long period of time, or if the intervals are too long.
Start stirring to avoid soil agglutination and drying.

It is a schematic diagram which shows the external structure of the apparatus of Example 1 of this invention. It is a schematic diagram which shows the internal structure of the collection tub on the collection tube side of the apparatus of Example 1 of this invention. It is a schematic diagram which shows the internal structure of the collection tub on the gas pipeline side of the apparatus of Example 1 of this invention. It is a schematic diagram which shows the rotation mechanism, the stirring mechanism and the sleeve rod structure of the apparatus of Example 1 of this invention. It is a schematic diagram which shows the internal structure of the rotation mechanism and the stirring mechanism of the apparatus of Example 1 of this invention. It is a schematic diagram which shows the structure inside the housing of the apparatus of Example 1 of this invention. It is a schematic diagram which shows the annular gear plate structure of the apparatus of Example 1 of this invention. It is a schematic diagram which shows the steel wire net structure of the apparatus of Example 1 of this invention. It is a schematic diagram which shows the soft plastic filtration net structure of the apparatus of Example 1 of this invention. It is a schematic diagram which shows the rigid plastic filtration net structure of the apparatus of Example 1 of this invention. It is a schematic diagram which shows the inner rod structure of the apparatus of Example 1 of this invention. It is a schematic diagram which shows the roller motor and the roller structure of A place in FIG. The schematic diagram which shows the internal structure of the rotation mechanism and the stirring mechanism of Example 2 of this invention.

[Explanation of code]
1 Collection tub 11 Upper tub body 12 Lower tub body 121 Opening 122 Collection plate 123 Collection groove 124 Circular protrusion 125 Roller motor 126 Roller 13 Sampling pipe 14 Swivel pump 15 Steel wire net 16 Quartz sand particles 17 Soft plastic filtration net 18 Hard plastic filtration Net 19 Threaded tub 2 Protective net 3 Rotating mechanism 31 Housing 311 Circular groove 32 Circular gear plate 321 Circular plate 322 Fixed plate 33 Rotating motor 34 First gear 4 Stirring mechanism 41 Second gear 42 Driven gear 43 Gear crawler 44 Bulldozer Plate 5 Sleeve rod 51 Inner rod 511 Strip-shaped protrusion 512 Male thread 52 Outer rod 521 Chute 522 Limiting part 53 Drill bit 531 Spiral steel plate 532 Diamond tip 6 Gas pipeline 61 Dual-purpose fan 62 Gas four-way valve 621 First gas conduit 622 Second gas conduit 623 Third gas conduit 7 Liquid level sensor 8 Controller 9 Water metal detector

Hereinafter, the technical solution of the embodiment of the present invention will be clearly and completely described with reference to the drawings in the embodiment of the present invention. Terms such as "front and back" and "left and right" used in the embodiments of the present invention are used for explanatory purposes only and indicate or imply relative importance or the location of technical features indicated. I can't understand to imply.

Example 1
As shown in FIGS. 1 and 2, the intelligent collection and analysis device for integrated collection and analysis of groundwater deliquescent is a collection tub 1, a protective net 2 located at the top of the collection tub 1.
The rotation mechanism 3 located at the upper part of the protective net 2 and the stirring mechanism 4 connected to the lower part of the rotation mechanism 3 are included.
As shown in FIGS. 2 and 8 to 10, the collecting tub 1 is divided into an upper tub main body 11 and a lower tub main body 12, and a set of sampling pipes 13 is provided on one side of the inner wall of the upper tub main body 11, and the sampling pipe 13 is provided. A perturbation pump 14 fixed to the inner wall of the upper tub main body 11 is provided in the central portion of the above, and the peristaltic pump 14 is a commercially available speed-adjustable peristaltic pump whose outer structure is adjusted according to the collection tub 1. , The upper end of the sampling pipe 13 is connected to the collecting bolt outside the collecting tub 1, the lower end of the sampling pipe 13 is located at the bottom of the upper tub main body 11, and the portion of the sampling pipe 13 in contact with the perturbing pump 14 is the hose. The other part of the sampling pipe is a corrosion resistant PE water supply pipe, a filtering component is provided on the upper part of the collecting tub 1, and the filtering component includes a steel wire net 15 located on the upper surface of the upper tub main body 11 and is made of steel. Line net 1
A layer of quartz sand particles 16 is provided at the bottom of 5, a layer of soft plastic filtration net 17 is provided at the bottom of the quartz sand particles 16, and a hard plastic filtration net 18 is provided at the bottom of the soft plastic filtration net 17. , A filtration component is provided on the upper part of the collecting tub 1, a threaded tub 19 is fixedly connected to the center of the inside of the upper tub body 11, and the upper part of the threaded tub 19 is provided.
The lower part is connected so that it can be sealed corresponding to the upper part and the lower part of the upper tub body 11.
As shown in FIGS. 4 to 7, the rotation mechanism 3 is a housing 3 fixedly connected to the protective net 2.
1. The rotary motor 33 includes a rotary gear plate 32 rotatably connected to the inside of the housing 31 and a rotary motor 33 located on one side of the inner bottom portion of the housing 31, and the rotary motor 33 is a commercially available double output shaft three-phase. The external structure of the asynchronous motor is adjusted according to the rotation mechanism 3. A rack is provided on the inner wall of the annular gear plate 32, and a first gear 34 is provided in the rack by meshing with each other. The output end is connected to the center of the first gear 34, and the annular gear plate 32 includes an annular plate 321 and a fixed plate 322 arranged and fixedly connected inside the annular plate 321 and located above the fixed plate 322. The annular plate 321 is rotatably connected to the annular groove 311 provided on the inner top surface of the housing 31, and the annular plate 32 is rotatably connected by the annular groove 311.
A rack is provided on the inner wall of the annular plate 321 located below the fixing plate 322 to prevent the escape of 1, and a sleeve rod 5 is fixedly provided in the center of the bottom of the fixing plate 322 of the annular gear plate 32 to provide a sleeve. The rod 5 is configured by fitting an outer rod 52 and an inner rod 51 extending into a threaded tub 19, a drill bit 53 is provided at the bottom of the inner rod 51, and both sides of the upper end of the inner rod 51. A strip-shaped protrusion 511 movably engaged with the chute 521 provided on the inner wall of the outer rod 52 is provided, a male screw 512 is provided on the outer wall at the center of the inner rod 51, and the male screw 512 is the inner wall of the threaded tub 19. The outer wall of the inner rod 51 between the lower part of the male screw 512 and the drill bit 53, and the male screw 5 are meshed with the female screw provided on the machine.
There is a smooth surface between the top of the 12 and the strip-shaped protrusion 511, the bottom of the inner rod 51 extends from the threaded tub 19 into the lower tub body 12, and the strip-shaped protrusion 511 is provided at the bottom of the outer rod 52. A limiting unit 522 is provided for stopping, and the shooting 5 is provided by the limiting unit 522.
The bottom of 21 is filled and closed, stripped protrusions 511 slide more than necessary along chute 511, avoiding the inner rod 51 separating from the outer rod 52, and the upper half of the drill bit 53 is soil. Spiral steel plate 531 for accumulating samples, the lower half of the drill bit 53 is a diamond tip 532,
As shown in FIGS. 4, 5 and 11, the lower output end of the rotary motor 33 penetrates the bottom of the housing 31 and is connected to a stirring mechanism 4 for rotating the soil in the protective net 2, and is provided in the stirring mechanism 4. The center of the upper surface of the second gear 41 is connected to the output end of the lower part of the rotary motor 33, and the second gear 41 is connected to the output end.
A set of driven gears 42, which are meshed and connected to each other on both sides of the gear 41, is provided, and a second gear 41 is provided.
The gear 41 is symmetrical with respect to the sleeve rod 5, and the driven gear 42 is also provided at a position flush with the second gear 41. Rotatably connected to the bottom of the housing 31, gear crawlers 43 on the outside of the three sets of driven gears 42.
The three sets of driven gears 42 are rotatably connected in synchronization with the rack provided inside the gear crawler 43, and four sets of bulldozer plates at equal distances are connected to the outside of the gear crawlers 43 of each stage. 44 is provided, a gear crawler 43 and a bulldozer plate 44.
Is made of steel material;
As shown in FIGS. 3 and 12, an opening 121 for passing the drill bit 53 is provided at the bottom of the lower tub main body 12, and a collection plate 1 is provided at the bottom of the lower tub main body 12 around the opening 121.
22 is provided, an annular collection groove 123 is provided at the outer end of the collection plate 122, a gas pipeline 6 is provided on one side of the inner wall of the upper tub main body 11, and the upper portion of the gas pipeline 6 is outside the collection tub 1. Connected to a dual-purpose fan 61, the bottom of the gas pipeline 6 is connected to a gas four-way valve 62 sealed and fixed between the upper tub body 11 and the lower tub body 12, and the gas four-way valve 62 is commercially available. The external structure of the metal-sealed four-way ball valve is adjusted according to the above device. The gas four-way valve 62 is branched into three sets of gas pipelines, and the first gas pipeline 621 is the bottom of the upper tub main body 11. The second gas pipeline 622 leads to the drill bit 53, the third gas pipeline 623 leads to the collection groove 123, and the collection plate 122 is inclined downward from the center toward the periphery to the bottom of the collection plate 122. An annular groove is provided, and the annular groove rotates the collection plate 122 together with the annular protrusion 124 provided on the bottom surface of the lower tub main body 12, and the third gas conduit 6 is provided.
A roller motor 125 is provided on the side of 23 near the collection plate 122, and the roller motor 125 is a commercially available horizontal gear reduction motor whose external structure is adjusted according to the above device, and has an output below the roller motor 125. The end is connected to a roller 126 for rotating the collection plate 122.
As shown in FIG. 2, a liquid level sensor 7 is provided in the center of one side of the inner wall of the upper tub main body 11, and the position of the liquid level sensor 7 is adjusted to the position of the 300 mL leached liquid in the upper tub main body 11. The liquid level sensor 7 is a commercially available infrared liquid level sensor whose external structure is adjusted according to the upper tub main body 11, and the liquid level sensor 7 is connected to a controller 8 located at the top of the side wall of the upper tub main body 11. The controller 8 is a commercially available S7-400 PLC controller, and the controller 8 is electrically connected to the motion pump 14 via an electromagnetic relay to control the on / off of the motion pump 14 and to control the on / off of the motion pump 14 and the upper tub body 11. A water metal detector 9 is provided at the bottom, the water metal detector 9 is a commercially available portable water metal detector for HM5000P, and the water metal detector 9 is connected to a data collection system outside the collection tub 1. To.
The principle and method of operation for collecting the groundwater dewatering solution by applying the intelligent collection and analysis device for collecting and analyzing the above-mentioned groundwater dewatering solution in an integrated manner are as follows.
This device is embedded in the soft and permeable soil of agricultural land, and the protective net 2 is 40c from the ground.
Place it at m, debug the device, then return the excavated soil to its original location and start collecting and analyzing groundwater deliquescent.

The operating principle of the peristaltic pump 14 is as follows.
When the underground water-soluble liquid is leached from the upper soil, it is sequentially filtered by the quartz sand particles 16, the soft plastic filtration net 17, and the hard plastic filtration net 18, and then enters the upper tub main body 11, and the liquid level becomes liquid. Immediately after reaching the height of the surface sensor 7 and the liquid level sensor 7 detects the leaching liquid, a signal is transmitted to the controller 8, and the controller 8 controls the electromagnetic relay to control the perturbation pump 1.
4 is opened, the opening time of the peristaltic pump 14 is set in advance, and the peristaltic pump 14 is set to 3 within the set time.
After transporting 00 mL of the leached liquid to the collection bolt on the ground, the controller 8 closes the peristaltic pump 14 via an electromagnetic relay to complete the transport of the leached liquid, while at the same time the data collection system on the ground performs one leaching liquid. The collection time was recorded, the leaching rate was calculated, and the metal element content of the leaching solution was immediately monitored by the water metal detector 9. At this time, there was no leaching solution in the upper tub body 11 and the relay continued from the upper soil. When the leached liquid is leached and the height of the liquid level reaches the height of the liquid level sensor 7 again, the above process is repeated to carry out the next transportation.

The operating principle of the rotation mechanism 3 is as follows.
When it is necessary to sample the soil below the collection tub 1 and compare and analyze the content of groundwater heavy metal above and below the device and the soil humidity, the rotary motor 33 rotates the upper first gear 34 clockwise. When the first gear 34 is rotated, the annular gear plate 32 meshed with the first gear 34 rotates clockwise along the annular groove 311 and the sleeve rod 5 provided in the middle of the central fixing plate 322 of the annular gear plate 32. Also rotates clockwise in synchronization, and when one cycle of turning on and off the peristaltic pump 14 is completed, the rotation mechanism 3 is turned on and one soil sampling is performed to perform one soil sampling, and the water quality above and below the collection tub 1 and the metal in the soil. Compare the element content and so on.
The operating principle of the sleeve rod 5 is as follows.
When the sleeve rod 5 rotates clockwise, the male screw 512 provided at the center of the inner rod 51 meshes with the female screw provided in the threaded tub 19 and rotates, and the inner rod 51 rotates along the threaded tub 19. The strip-shaped protrusion 511 provided at the upper end of the inner rod 51 slides downward in the chute 521 of the outer rod 52, and the inner rod 51 moves downward along the outer rod 52 at the same time. , The drill bit 53 rotates through the opening 121 to the deeper soil below until the strip-shaped projection 511 comes into contact with the limiting portion 522, at which time the rotary motor 33 reverses and the upper first gear 34 When the first gear 34 rotates, the annular gear plate 32 meshed with the first gear 34 rotates counterclockwise around the annular groove 311 and the sleeve rod 5 also rotates counterclockwise in synchronization with the rotation. Then, the inner rod 51 moves upward along the threaded tub 19 and the outer rod 52 to its original position, and the soil collected at this time is accumulated on the spiral steel plate 531.

The operating principle of the gas pipeline 6 is as follows.
Open the valve of the second gas conduit 622 on the gas four-way valve 62, turn on the dual-purpose fan 61, blow air into the second gas conduit 622, and collect the soil accumulated on the spiral steel plate 531. Width into the plate 122 and then dropped into the collection groove 123 to open the valve of the third gas conduit 623 on the gas four-way valve 62, turn on the dual purpose fan 61 and turn on the third gas conduit 6
Air is sucked into 23 to suck and collect soil, and at the same time the roller motor 125 is turned on to rotate the roller 126, which rubs against the collecting plate 122 during rotation and rotates the collecting plate 122 along the annular groove. When it is rotated once, all the soil in the collection groove 123 is sucked and collected, and the valve of the first gas conduit 621 on the gas four-way valve 62 is opened.
At the same time, high-temperature steam is injected into the first gas conduit 621 to clean the inside of the upper tub main body 11.
The operating principle of the stirring mechanism 4 is as follows.
When the rotation mechanism 3 operates, the rotation motor 33 rotates the second gear 41 below the rotation mechanism 3.
The second gear 41 rotates the driven gears 42 on both sides thereof to rotate the gear crawler 43 to 3.
The soil inside the protective net 2 is agitated by the bulldozer plate 44 at the same time as it is rotated around the driven gear 42 of the set, and the soil is further exchanged, which adversely affects the collection efficiency of the leached liquid due to the decrease in the soil leaching capacity. If it is prevented, or if the water content or porosity in the soil is too strong, the agitation mechanism may be manually opened and the soil may be agitated and replaced.

Example 2
Unlike the first embodiment, in the present embodiment, the second gear 41 is omitted, and one set of the driven gears 42 is directly driven and rotated by the rotary motor 33.
As shown in FIG. 13, the output end of the lower part of the rotary motor 33 penetrates the bottom of the housing 31 and is connected to a stirring mechanism 4 for rotating the soil in the protective net 2, and three sets of driven gears are driven in the stirring mechanism 4. Gears 42 are provided, of which the center of the top surface of one set of driven gears 42 is connected to the lower output end of the rotary motor 33, and the center of the top surface of the other two sets of driven gears 42 is a set of connecting rods. It is rotatably connected to the bottom of the housing 31 via a gear crawler 43 provided on the outside of the three sets of driven gears 42, and the three sets of driven gears 42 mesh with a rack provided on the inside of the gear crawler 43 to synchronize. And rotatably connected, four sets of bulldozer plates 44 are provided on the outside of the gear crawler 43 of each stage at equal distances, and both the gear crawler 43 and the bulldozer plate 44 are made of steel material.

Example 3
In this embodiment, the set position and the set number of sets of the driven gear 42 are different from those in the first embodiment.
The lower output end of the rotary motor 33 penetrates the bottom of the housing 31 and is connected to a stirring mechanism 4 for rotating the soil in the protective net 2, and is connected to the stirring mechanism 4 on the upper surface of the second gear 41 provided in the stirring mechanism 4. A set of driven gears 42, the center of which is connected to the lower output end of the rotary motor 33 and meshed with it on both sides of the second gear 41, are provided with respect to the sleeve rod 5 with respect to the second gear 41. Two sets of driven gears 42 are also provided at locations that are symmetrical and flush with the second gear 41, and 4
The center of the upper surface of the set of driven gears 42 is rotatably connected to the bottom of the housing 31 via a set of connecting rods, and a gear crawler 43 is provided on the outside of the four sets of driven gears 42. The 42 is rotatably connected in synchronization with a rack provided inside the gear crawler 43, and four sets of bulldozer plates 44 are provided on the outside of the gear crawler 43 at each stage at equal distances with the gear crawler 43. Both the bulldozer plates 44 are made of steel material.

Comparative Example 1
Unlike the first embodiment, in this comparative example, the second gear 41 of the stirring mechanism 4 is not driven by the output end of the lower part of the rotary motor 33 to rotate, but is driven by a set of single motors to rotate. do.

Comparative Example 2
Unlike the first embodiment, the stirring mechanism 4 is not provided in this comparative example.
Experimental Example 1
Within one sampling cycle (3) with Examples 1 to 3 and Comparative Examples 1 and 2 as experimental subjects.
The soil above the collection device is agitated using the agitation mechanism 4 in (00 ml leaching solution), and the number of agitation is 0.
The effect of the number of times of stirring on the leaching efficiency is affected by observing the leaching time of 300 ml of the leaching solution under different stirring times conditions, with one turn of the gear crawler 43 being one stirring, increasing from the number of times to the nth order. get.
The stirring timing is determined according to the time of the previous sampling cycle, and assuming that the time of the first sampling cycle is t ₁ , the stirring timing at the time of the second sampling is 1 /.
Assuming that 2t ₁ is set and the time of the second sampling cycle is t ₂ , the stirring timing at the time of the third sampling is set to 1 / 3t ₂ and 2 / 3t ₂ , respectively, and so on.
Among them, in Comparative Example 2, since the stirring mechanism 4 is not provided, the number of stirrings is set to 0, and the experimental results are shown in Table 1.
Table 1 Leaching time under different stirring times in Examples 1 to 3 and Comparative Examples 1 and 2.

As can be seen from the table above, each set of data has the following effects: Stirring the soil can promote the flow of water in the soil and the circulation between the soils, shortening the leaching time and increasing the leaching rate.
As the number of stirrings increases, the shorter the leaching time, the faster the leaching rate, and the effect of increasing the leaching rate by stirring 6 or 7 times is not clear, which is beneficial for water flow in the soil by proper stirring. It is shown that there is, and the most preferable number of times of stirring is 5 times.
As can be seen by comparing the first and second embodiments, in the second embodiment, the second gear 41 is omitted, and one set of the driven gears 42 thereof is directly driven and rotated by the rotary motor 33, and a part of the second gear 41 is omitted. Although the structure of the device can be omitted and the entire device structure can be simplified, the stirring effect is affected to a certain extent and the effect of improving the leaching rate is lower than that of the first embodiment. Therefore, in the first embodiment, the second gear is used. Rotating the driven gear 42 by 41 promotes the improvement of leaching efficiency.
As can be seen by comparing Example 1 and Example 3, in Example 3, three sets of driven gears 42 are provided in a rectangular shape, so that the stirring effect can be improved to some extent in a short time and the leaching efficiency can be improved. When stirring only once, the leaching efficiency of Example 3 is higher than that of Example 1, because the stirring area is large as in Example 3, but the improvement of the leaching efficiency is hindered as the number of stirrings increases. After stirring 7 times, the leaching efficiency of Example 3 becomes lower than that of Example 1. Therefore, in consideration of the above, the setting method of the driven gear 42 of Example 1 is most preferable.
As can be seen by comparing Example 1 and Comparative Example 1, since the structures of both are the same and only the drive method is different, there is almost no difference in the influence on the leaching efficiency, and in Comparative Example 1, one set of motors is added. Therefore, since the narrow leaching space is inevitably narrower, the leaching amount is also reduced to some extent, and the leaching efficiency is indirectly lowered. The setting method for simultaneously driving the stirring mechanism 4 and the stirring mechanism 4 is most preferable.
As can be seen by comparing Example 1 and Comparative Example 2, in Comparative Example 2, since the upper soil cannot be agitated, the water flow in the soil cannot be promoted, and the leaching efficiency is relatively lower than that of Example 1.

Example 4
In this embodiment, the set position of the liquid level sensor 7 in the upper tub main body 11 is different from that of the first embodiment.
As shown in FIG. 2, a liquid level sensor 7 is provided in the center of one side of the inner wall of the upper tub main body 11, and the position of the liquid level sensor 7 is adjusted to the position of the 450 mL leached liquid in the upper tub main body 11. The liquid level sensor 7 is a commercially available infrared liquid level sensor whose external structure is adjusted according to the upper tub main body 11, and the liquid level sensor 7 is connected to a controller 8 located at the top of the side wall of the upper tub main body 11. Will be done.
Example 5
In this embodiment, the set position of the liquid level sensor 7 in the upper tub main body 11 is different from that of the first embodiment.
As shown in FIG. 2, a liquid level sensor 7 is provided in the center of one side of the inner wall of the upper tub main body 11, and the position of the liquid level sensor 7 is adjusted to the position of the 600 mL leached liquid in the upper tub main body 11. The liquid level sensor 7 is a commercially available infrared liquid level sensor whose external structure is adjusted according to the upper tub main body 11, and the liquid level sensor 7 is connected to a controller 8 located at the top of the side wall of the upper tub main body 11. Will be done.
An appropriate height of the liquid level sensor 7 may be set according to the type of soil to be measured, the size of the permeation rate, and the permeation rate.

Experimental Example 2
Measurement experiments were performed on the leached liquid collection and analyzers of Examples 1, 4 and 5, and they were embedded in soil containing groundwater and having a certain amount of heavy metal contamination. The soil used in the experiments is representative of the Changjiang Delta region. The soil is yellow mud and sandy soil. First, the leaching rate of groundwater is observed, and the measurement results are shown in Table 2.
Table 2 Leaching rates in Examples 1, 4, and 5

As can be seen from the above table, the leaching rates of the three sets of examples are different, and under similar weather conditions, the smaller the volume of the leaching solution, the faster the leaching rate, and the larger the volume of the leaching solution, the lower the leaching rate. However, this indicates that the leaching rate at the initial stage of leaching is high, and in the absence of agitation, rainfall or other treatment, the leaching rate of continuous leaching tends to decrease over time.

Example 6
In this embodiment, the set number of sets of the bulldozer plate 44 is different from that of the first embodiment.
Gear crawlers 43 are provided on the outside of the three sets of driven gears 42, and the three sets of driven gears 42 are rotatably connected in synchronization with the rack provided on the inside of the gear crawlers 43 to be rotatably connected to each stage. Six sets of bulldozer plates 44 are provided on the outside of the 43 at equal distances.
Both the gear crawler 43 and the bulldozer plate 44 are made of steel.

Example 7
In this embodiment, the set number of sets of the bulldozer plate 44 is different from that of the first embodiment.
Gear crawlers 43 are provided on the outside of the three sets of driven gears 42, and the three sets of driven gears 42 are rotatably connected in synchronization with the rack provided on the inside of the gear crawlers 43 to be rotatably connected to each stage. Eight sets of bulldozer plates 44 are provided on the outside of the 43 at equal distances.
Both the gear crawler 43 and the bulldozer plate 44 are made of steel.
It is not preferable that the number of sets of the bulldozer plate 44 is too large or too small. If the number of sets is too large, the rotation of the gear crawler 43 is affected, and if the number of sets is too small, the effect of stirring the soil is not good. Therefore, the four sets in Example 1 are optimal.

Claims (5)

The collecting tub (1), the protective net (2) located on the upper part of the collecting tub (1), the rotating mechanism (3) located on the upper part of the protective net (2), and the rotating mechanism (3). Includes a stirring mechanism (4) connected to the bottom of the
The collecting tub (1) is divided into an upper tub main body (11) and a lower tub main body (12), and a set of sampling pipes (13) is provided on one side of the inner wall of the upper tub main body (11). A perturbation pump (14) fixed to the inner wall of the upper tub body (11) is provided in the center of the pipe (13), a filtering component is provided on the upper part of the collection tub (1), and the upper tub body (11) is provided. A threaded tub (19) is fixedly connected to the center of the inside, and the upper part and the lower part of the threaded tub (19) are connected to be sealable corresponding to the upper part and the lower part of the upper tub body (11).
The rotation mechanism (3) has a housing (3) fixedly connected to the protective net (2).
1) An annular gear plate (32) rotatably connected to the inside of the housing (31).
And a rotary motor (33) located on one side of the bottom in the housing (31), a rack is provided on the inner wall of the annular gear plate (32), and the rack is provided with a first gear (34).
) Is engaged, the upper output end of the rotary motor (33) is connected to the center of the first gear (34), and the sleeve rod (5) is fixedly connected to the center of the bottom of the annular gear plate (32). The sleeve rod (5) is provided, and the sleeve rod (5) is configured by fitting an outer rod (52) and an inner rod (51) extending into the threaded tub (19), and a drill bit is provided at the bottom of the inner rod (51). (53) is provided, and the outer rod () is provided on both sides of the upper end of the inner rod (51).
A strip-shaped protrusion (521) movably engaged with a chute (521) provided on the inner wall of 52).
511) is provided, and a male screw (512) is provided on the central outer wall of the inner rod (51).
The male screw (512) is meshed with a female screw provided on the inner wall of the threaded tub (19).
Between the lower part of the male screw (512) and the drill bit (53), and the male screw (512).
The outer wall of the inner rod (51) between the upper part of the rod and the strip-shaped protrusion (511) has a smooth surface, and the bottom of the inner rod (51) is from the threaded tub (19) to the inside of the lower tub body (12). Stretch to
The lower output end of the rotary motor (33) penetrates the bottom of the housing (31) and is connected to a stirring mechanism (4) for rotating the soil in the protective net (2), and the lower tub main body (12). )
An opening (121) for the drill bit (53) to pass through is provided at the bottom of the bottom, and a collection plate (122) is provided at the bottom of the lower tub body (12) around the opening (121). An annular collection groove (123) is provided at the outer end of the collection plate (122), and a gas pipeline (6) is provided on one side of the inner wall of the upper tub main body (11).
A liquid level sensor (7) is provided in the center of one side of the inner wall of the upper tub main body (11), and the liquid level sensor (7) is attached to a controller (8) at the top of the side wall of the upper tub main body (11). Connected, the controller (8) is electrically connected to the perturbation pump (14), and the upper tub body (
A water quality metal detector (9) is provided at the bottom of the 11), and the water quality metal detector (9) is a collection tub (9).
1) Connected to an external data collection system,
Protective net (2) Groundwater deliquescent from the soil inside is tubed through a filtration component.
It can be collected in the main body (11),
Soil can be accumulated by the spiral steel plate (531) of the drill bit (53),
An intelligent collection and analysis device for integrated collection and analysis of groundwater deliquescent. The annular gear plate (32) includes an annular plate (321) and a fixed plate (322) located inside the annular plate (321) and fixedly connected to the annular plate (322). (321) is rotatably connected to an annular groove (311) provided on the inner top surface of the housing (31), and a rack is provided on the inner wall of the annular plate (321) below the fixing plate (322). The apparatus according to claim 1, wherein the apparatus is characterized by the above. A limiting portion (522) for stopping the strip-shaped protrusion (511) is provided on the bottom of the outer rod (52), and the upper half of the drill bit (53) is a spiral steel plate (531).
), And the lower half of the drill bit (53) is a diamond tip (532). .. The upper part of the gas pipeline (6) is an external dual-purpose fan (61) of the collection tub (1).
), And the bottom of the gas pipeline (6) is the upper tub body (11) and the lower tub body (12).
), Which is connected to a gas four-way valve (62) sealed and fixed, three sets of gas conduits are branched from the gas four-way valve (62), and the outlet of the first gas conduit (621) is on the top. The main body of the tub (1
The outlet of the second gas conduit (622) leading to the bottom of 1) is the drill bit (53).
), And the outlet of the third gas conduit (623) leads to the collection groove (123).
The apparatus according to claim 1. The collection plate (122) is inclined downward from the center toward the periphery, and the collection plate (122) is
An annular groove is provided at the bottom of the 122), and the annular groove rotates the collection plate (122) together with the annular protrusion (124) provided on the bottom surface of the lower tub main body (12) to rotate the collection plate (122).
A roller motor (125) is provided on the side of the 623) close to the collection plate (122), and the lower output end of the roller motor (125) is connected to the roller (126) for rotating the collection plate (122). The apparatus according to claim 4 , wherein the apparatus is characterized by the above.

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