JP7316485B1 - Apparatus and method for assessing mixing uniformity of agents for contaminated soil remediation - Google Patents

Abstract

A device and method for evaluating the mixing uniformity of agents for contaminated soil remediation. A device includes a sleeve pipe and an auger, one end of the sleeve pipe is detachably connected to the auger, a tightening mechanism is provided inside the other end of the sleeve pipe, and between both ends of the moving rod. A rotating leaf is provided to rotate around an auger to receive a soil sample, and a sampling box is provided on the outer wall of the clamping leaf, and the method is quantitative by means of an image acquisition device, computer analysis processing software and an arithmetic method. Based on the evaluation results, the present invention has a clamping mechanism that makes it difficult for the soil sample to escape from the sleeve pipe, and a sampling box that provides multiple soil sampling points on the outer wall of the pipe to facilitate the soil sampling process. At the same time, the evaluation method can scientifically evaluate the mixing uniformity of chemicals and contaminated soil. [Selection drawing] Fig. 11

Description

The present invention belongs to the technical field of contaminated soil sampling, and specifically relates to an apparatus and method for evaluating mixing uniformity of chemicals for remediation of contaminated soil.

Currently, contaminated soil remediation techniques such as heavy metal stabilization, chemical oxidation, and chemical reduction involve the use of remediation agents and mixing reactions, but in practice, no attention is paid to the degree of mixing uniformity. , it is often difficult to reliably remediate contaminated soil, and the use of remediation agents increases, resulting in higher remediation costs and longer remediation cycles. Some patents use magnetic markers to assess the homogeneity of mixtures, but not all restoratives have magnetic properties.
It is difficult to guarantee the actual application effect.
In addition, existing samplers are usually inserted vertically into the soil and taken out, and during the process of taking out the sampling rod from the soil, the soil inside the rod escapes from the sampling port, damaging the soundness of the collected soil sample. This needs to be further improved as it affects the accuracy of the sample data obtained.

The present invention provides an apparatus for evaluating mixing uniformity of agents for remediation of contaminated soil, which comprises:
a sleeve pipe and an auger, wherein one end of the sleeve pipe is detachably connected to the auger;
A handle is rotatably connected to the outside of the sleeve pipe, the handle passes through the other end of the sleeve pipe via a handle rod, and a tightening mechanism is provided inside the other end of the sleeve pipe, The tightening mechanism is provided with a first screw collar, a second screw collar and a plurality of sets of tightening lobes, the first screw collar and the second screw collar are sequentially fitted on the handle rod from top to bottom, and The connection base provided on the upper part of the attached leaf is connected to the first screw collar and the second screw collar through the connection rod, respectively, and the connection rod is rotatable to the connection base, the first screw collar and the second screw collar. The threads provided on the handle rod which is connected and located on the first threaded collar are in the opposite direction to the threads provided on the handle rod which is located on the second threaded collar and the above installation allows the handle rod to be When rotating, the first screw collar and the second screw collar respectively move up and down along the handle rod, and the connection of the connecting rod brings the clamping leaf closer to the inside, realizing clamping of the soil sample,
The auger at the connection with one end of the sleeve pipe is provided with a plurality of sets of rotary leaves for opening and closing the opening of the auger, one end of the rotary leaves is provided with a moving rod, and the tightening leaf and the end face of the auger are provided with , a first sliding groove slidably connected to one end of the moving rod, and a second sliding groove slidably connected to the other end of the moving rod. Each of the two sliding grooves has an arcuate structure with one end close to the outer wall of the clamping leaf and the other end close to the inner wall of the clamping leaf. During the closing process, the moving rod rotates to move the leaf to close the auger opening, making it difficult for the soil sample to escape from the sleeve pipe.
Further, the inside of the clamping lobe is hollow, the inner wall thereof is provided with a plurality of sets of nail holes, the clamping lobe is provided with a nail plate for moving and bending by using a moving rod, and the nail plate is is slidably connected to the inner bottom surface of the clamping lobe, the nail plate is connected to the inner wall of the clamping lobe via a first spring, and the nail plate has nail holes corresponding to the nail holes in one-to-one correspondence. a plurality of sets of nails are provided for passing through the nail so that during the closing process of the clamping leaf, when the moving bar moves between the first slide groove and the second slide groove, the nail passes through the nail After passing through the hole, the friction between the clamping leaf and the soil sample increases and the soil sample can be gripped, and the installation of the first spring resets the nail plate inside the clamping leaf during the opening process of the clamping leaf. be done.
Further, a limiting slide rail is provided on the inner bottom surface of the clamping lobe for guiding a nail to fit into the nail hole, and the nail plate is slidably connected to the limiting slide rail. A sliding hole is provided so that the nail plate can limit the sliding, and the engagement between the nail on the nail plate and the nail hole on the clamping leaf can be realized.
Further, a limiting base is provided on the inner bottom surface of the tightening leaf near the outer wall of the tightening leaf, and the contact surface of the limiting base with the moving rod matches the curvature of the first slide groove, and the first slide To make the movement of a moving rod in a moving groove more stable.
Moreover, the handle rod is provided with a limiting groove rotatably connected to the sleeve pipe to limit the sleeve pipe so that the handle can rotate relative to the sleeve pipe to push the sleeve pipe for use.
Further, a plurality of sets of sampling boxes are provided on the outer wall of the clamping leaf, and openings are provided in the sleeve pipe at positions corresponding to the sampling ports of the sampling boxes for allowing the sampling boxes to pass through the openings. , There is a hole cover connected to the sleeve pipe and the torsion spring. By installing the sampling box, when the clamping leaf is opened and closed, the sampling box moves, and the hole cover is pushed to open and close, realizing sampling of the sampling box. do.
Further, the sampling port of the sampling box is higher than the contact surface between the sampling box and the clamping lobe, the contacting surface is slidably engaged with the outer wall of the clamping lobe, and the outer wall of the clamping lobe is provided with a tab. said tab is connected to the bottom end of the sampling box via a third spring, and the above installation causes the sampling box to be tilted upwards when passing through the hole, facilitating sampling and removing the soil sample when the sampling box is pulled back. can be made easier to wrap.
The present invention further provides a method for evaluating mixing uniformity of agents for remediation of contaminated soil, the method comprising:
S1: According to the shape information of the pile, any one method of system random, expert judgment, zoning or system pointing is used to determine the sampling points, and the sleeve pipe is placed into the soil sample of each of the sampling points respectively. insert and
the clamping leaf clamping the soil sample by rotating the handle, the rotating leaf receiving the soil sample and then removing it for multi-point sampling of 3-10 sampling points;
S2: Using an image acquisition device to continuously acquire sample cross-sectional images of soil cross-sections at different depths, the file format of the sample cross-sectional images is a file format that can be imported into a computer system, and the image acquisition device is being a digital camera or mobile phone;
S3: A step of performing digital processing on the sample cross-sectional image of step S2 by analysis processing software of the computer system to obtain a digital image that visualizes the color difference of the pile component;
S4: constructing a model and a calculation method to analyze and calculate the color difference of the pile component obtained in step S3 to obtain a quantitative evaluation result;
Specifically, the step S4 is
1) Distinguishing the distribution of contaminated soil particles and remediation agent particles from the digital image based on different colors of pile components, and displaying the contaminated soil particles and remediation agent particles in the form of spots in the digital image;
2) using the gridline method to uniformly slice the digital image in a cross-shaped grid to obtain different image zoning situations;
3) counting the number of spots representing the restorative agent particles within each of the image zonings of step 2);
4) Statistically and analyzing the degree of difference in spot number of repair agent particles between all image zonings, wherein the statistical analysis calculation indicators are the average value and the standard difference;
5) respectively calculating the coefficient of variation of each said sampling point through equation (1) to obtain the uniform distribution of the reparative agent particles;
CV=SD/Mean*100% (1)
where CV is the coefficient of variation of the sampling points, SD is the standard difference, and Mean
is the average value and
6) Summarizing the CV values of each sampling point and averaging the CV values of each sampling point to obtain an arithmetic mean;
1) Based on the arithmetic mean value calculated in step 6), strongly fluctuate if CV value >100%,
Medium fluctuation when CV value is 100% to 40%, low fluctuation when CV value is 40% to 10%, C
Evaluating the mixing uniformity of contaminated soil and remediation agent in piles comprehensively according to the method with V value < 10% as weak variation.

The invention has the following beneficial effects.
(1) The present invention provides a clamping mechanism and auger installation that allows the soil to be clamped and collected by rotating the handle, the leaf to be rotated to seal the auger end, and the soil sample to be collected. It is not easy to escape from the sleeve pipe, keeps the integrity of the soil sample, and the sampling effect is better.
(2) The present invention can achieve multi-point sampling of different depth soil piles on the outer wall of the sleeve pipe at the same time by rotating the handle and moving the clamping leaf through the installation of the sampling box, so that the soil sampling facilitate the process of
(3) The present invention uses computer analysis processing software and calculation methods to quickly and scientifically respond to the mixing degree of chemicals and soil, and to comprehensively evaluate the mixing uniformity of piles.

It is a schematic diagram which shows the external appearance of this invention. FIG. 4 is a schematic diagram showing the external appearance of the tightening mechanism and the handle of the present invention; It is a schematic diagram which shows the structure of the tightening mechanism of this invention. FIG. 4 is a cross-sectional view of the main part of the clamping leaf of the present invention; FIG. 3 is a side cross-sectional view of a clamping leaf of the present invention; FIG. 4 is a cross-sectional top view of a clamping leaf of the present invention; FIG. 4 is an external view showing the bottom surface of the clamping leaf of the present invention; FIG. 4 is a schematic diagram of the nail plate of the present invention slidably connected to the inner bottom surface of the clamping lobe; Fig. 2 is an assembly diagram of the nail board and auger of the present invention; 1 is a schematic diagram showing an auger and moving rod of the present invention; FIG. It is a schematic diagram which shows the external appearance of Example 2 of this invention. Fig. 10 is an assembled external view of the sampling box in Example 2 of the present invention; Fig. 10 is an assembled side view of the sampling box in Example 2 of the present invention; 1 is a flowchart of a method of evaluating drug blend uniformity of the present invention;

[Description of symbols]
1 sleeve pipe 11 tightening leaf 111 connection base 112 nail plate 1121 limit base 1122 nail 1123 first spring 113 nail hole 114 first sliding groove 115 tab 116 third spring 12 hole cover 13 sampling box 2 handle 21 handle rod 211 limit Groove 22 First screw collar 23 Second screw collar 24 Connecting rod 3 Auger 31 Second sliding groove 32 Moving rod 321 Second spring 33 Rotary leaf

Hereinafter, the present invention will be described in more detail with reference to specific embodiments in order to better reflect the advantages of the present invention.
Example 1
As shown in FIGS. 1, 2 and 10, an apparatus for evaluating mixing uniformity of a chemical for remediation of contaminated soil comprises a sleeve pipe 1 and an auger 3, one end of the sleeve pipe 1 being screwed into the auger 3. A handle 2 is connected to the sleeve pipe 1 and is rotatably connected to the outside of the sleeve pipe 1. The handle 2 penetrates the other end of the sleeve pipe 1 via a handle rod 21, is provided with a tightening mechanism, said tightening mechanism includes a first screw collar 22, a second screw collar 23 and three sets of tightening leaves 11, allowing said handle rod 21 to rotate to sleeve pipe 1 A connected limiting groove 211 is provided.
2, 3 and 10, the first screw collar 22 and the second screw collar 23 are sequentially fitted on the handle rod 21 from top to bottom, and the connection provided on the top of the clamping leaf 11 The pedestal 111 is connected to the first screw collar 22 and the second screw collar 2 via the connecting rod 24, respectively.
3, the connecting rod 24 is rotatably connected to the connecting base 111, the first screw collar 22, the second screw collar 23;
the threads provided on the handle rod 21 located on the first threaded collar 22 are in the opposite direction to the threads provided on the handle rod 21 located on the second threaded collar 23;
A plurality of sets of rotary leaves 33 for opening and closing the opening of the auger 3 are provided on the auger 3 at the connection portion with one end of the sleeve pipe 1, and a moving rod 32 is provided at one end of the rotary leaves 33 to A first sliding groove 114 slidably connected to one end of the moving rod 32 and a second sliding groove 31 slidably connected to the other end of the moving rod 32 are formed on the end surfaces of the attached leaf 11 and the auger 3 . Each of the first sliding groove 114 and the second sliding groove 31 has an arc-shaped structure in which one end is close to the outer wall of the clamping leaf 11 and the other end is close to the inner wall of the clamping leaf 11. can be,
As shown in FIGS. 4, 5, 6, 7, 8 and 9, the inside of the clamping leaf 11 is hollow, and the inner wall thereof is provided with a plurality of sets of nail holes 113, and a moving rod is provided in the clamping leaf 11. A nail plate 112 is provided for moving and bending using the 32, said nail plate 112 is slidably connected to the inner bottom surface of the clamping leaf 11, and a nail 1122 is nailed to the inner bottom surface of said clamping leaf 11. A limiting slide rail 1125 is provided for guiding it to fit into the hole 113, said nail plate 112 is provided with a sliding hole 1124 slidably connected to said limiting slide rail 1125, and said The nail plate 112 is the first
A plurality of sets of nails 1122 are connected to the inner wall of the clamping leaf 11 via a spring 1123 and are provided in the nail plate 112 in one-to-one correspondence with the nail holes 113 to pass through the nail holes 113, A limiting base 1121 is provided on the inner bottom surface of the tightening leaf 11 near the outer wall of the attaching leaf 11, and the limiting base 1121
contact surface with the moving rod 32 coincides with the curvature of the first sliding groove 114,
The bottom end of said auger 3 is a cutting tip, and said sleeve pipe 1 is of stainless steel material.
A method of collecting and evaluating samples using the above apparatus includes:
S1: According to the shape information of the pile, any one method of system random, expert judgment, zoning or system pointing is used to determine the sampling points, and the sleeve pipe 1 is placed on the soil sample of each sampling point. The clamping leaf 11 clamps the soil sample by respectively inserting and rotating the handle 2, and the rotating leaf 33 picks up after receiving the soil sample, performing multi-point sampling of 8 sampling points;
S2: Using an image acquisition device to continuously acquire sample cross-sectional images of soil cross-sections at different depths, the file format of the sample cross-sectional images is a file format that can be imported into a computer system, and the image acquisition device is a step that is a digital camera;
S3: A step of performing digital processing on the sample cross-sectional image of step S2 by analysis processing software of a computer system to obtain a digital image that visualizes the color difference of the pile component, and the analysis processing software of the computer system is a computer Windows system. Matlab software of
is to segment the image and extract the feature parameters of the image,
S4: constructing a model and a calculation method to analyze and calculate the color difference of the pile component obtained in step S3 to obtain a quantitative evaluation result;
Specifically, the step S4 is
1) Distinguishing the distribution of contaminated soil particles and remediation agent particles from the digital image based on different colors of pile components, and displaying the contaminated soil particles and remediation agent particles in the form of spots in the digital image;
2) using the gridline method to uniformly slice the digital image in a cross-shaped grid to obtain different image zoning situations;
3) counting the number of spots representing the restorative agent particles within each of the image zonings of step 2);
4) Statistically and analyzing the degree of difference in spot number of repair agent particles between all image zonings, wherein the statistical analysis calculation indicators are the average value and the standard difference;
5) respectively calculating the coefficient of variation of each said sampling point through equation (1) to obtain the uniform distribution of the reparative agent particles;
CV=SD/Mean*100% (1)
where CV is the coefficient of variation of the sampling points, SD is the standard difference, and Mean
is the average value and
6) Summarizing the CV values of each sampling point and averaging the CV values of each sampling point to obtain an arithmetic mean;
7) Based on the arithmetic mean value calculated in step 6), strongly fluctuate if CV value >100%,
Medium fluctuation when CV value is 100% to 40%, low fluctuation when CV value is 40% to 10%, C
Evaluating the mixing uniformity of contaminated soil and remediation agent in piles comprehensively according to the method with V value < 10% as weak variation.
The device for evaluating the mixing uniformity of the above-mentioned contaminated soil remediation agent operates as follows.
First, after securing an open state in which the clamping leaf 11 is close to the sleeve pipe 1, push the handle 2 to insert the sleeve pipe 1 into the soil, and when the soil surface exceeds the sleeve pipe 1, rotate the handle 2, Under the rotation of the handle 2, the first screw collar 22 and the second screw collar 23 respectively move up and down along the threads on the handle rod 21, and the first screw collar 22 and the second screw collar 23 engage the connecting rod 24. drive, and drive the connecting rod 24 through the connecting base 111 so that the clamping leaf 11 can be brought closer to the inside,
When the clamping leaf 11 is brought closer to the inside, the moving rod 32 of the first slide groove 114 is moved to the first slide groove 114 .
and along the second sliding groove 31, and under the restriction of the movement of the moving rod 32 and the first sliding groove 114, the moving rod 32 pushes the nail plate 112 and moves in the tightening direction of the inner wall of the tightening leaf 11. and the nail 1122 on the nail plate 112 passes through the nail hole 113, and under the movement of the moving rod 32, the rotating leaf 33 is rotated around the center of the auger 3, and the opening of the auger 3 is sealed to realize sampling;
After that, the sleeve pipe 1 is pulled out, the handle 2 is rotated, the clamping leaf 11 is opened, the moving rod 32 is reset via the second spring 321, the nail plate 112 is reset via the first spring 1123, and rotates. The leaf 33 is reset to the edge position of the auger 3, and the soil sample is poured out. After the soil sample is poured out, a cross-sectional image of the sample is acquired using a digital camera and imported into the analysis processing software of the computer system. After processing, models and computational methods are built for analysis and evaluation.

Example 2
This example is a further improvement based on Example 1, and differs from Example 1 in the following points:
As shown in FIGS. 11, 12, and 13, three sets of sampling boxes 13 are provided on the outer wall of the clamping leaf 11, and the sleeve pipe 1 at a position corresponding to the sampling port of the sampling box 13 has a sampling box 13. A hole is provided for passing through, and a hole cover 12 is provided in which the sleeve pipe 1 is connected to the hole via a torsion spring,
The sampling port of the sampling box 13 is connected to the sampling box 13 and the clamp leaf 1
1 contact surface, said contact surface is slidably engaged with the outer wall of the clamping leaf 11 , and the outer wall of said clamping leaf 11 is provided with a tab 115 , said tab 115 engaging a third spring 116 . is connected to the bottom end of the sampling box 13 via the .
The principle of operation of this embodiment is basically the same as that of the first embodiment, except for the following points.
is closed, push the handle 2 to insert the sleeve pipe 1 into the soil through the auger 3,
After that, the handle 2 is rotated, the first screw collar 22 and the second screw collar 23 respectively move up and down along the thread on the handle rod, and the first screw collar 22 and the second screw collar 23 are connected to the connecting rod 24. , and the connecting rod 24 is driven to expand the clamping leaf 11 through the connecting base 111, and at this time, the clamping leaf 11 gradually approaches the sleeve pipe 1,
The sampling box 13 pushes the hole cover 12 outward, then the sampling box 13 performs sampling, then rotates the handle 2 to close the clamping leaf 11, and the hole cover 12 resets under the action of the torsion spring. Finally, the sleeve pipe 1 is pulled out, and the handle 2 is rotated to pour out the soil sample in the sampling box 13.

表２ ＳＡ２重金属安定化薬剤を用いた汚染土壌の混合均一性の総合的な評価状況

計算したＣＶ算術平均値から分かるように、ＳＡ１重金属安定化薬剤と汚染土壌の混合均
一度の総合的な評価結果は低変動であり、ＳＡ２重金属安定化薬剤と汚染土壌の混合均一
度の総合的な評価結果は中変動である。 Using the apparatus of Application Example 1, for two contaminated soils of the same mass using the SA1 and SA2 heavy metal stabilizing agents, the mixing uniformity of the SA1 and SA2 heavy metal stabilizing agents and the contaminated soil is determined, collecting and evaluating contaminated soil samples, the method comprising the steps of:
First, according to the shape information of the two piles after mixing the SA1 and SA2 heavy metal stabilizing agents and the contaminated soil, a pointing method of expert judgment was adopted, and for the contaminated soil pile using the SA1 heavy metal stabilizing agent 5-point sampling was carried out, a system random pointing method was adopted, 9-point sampling was carried out for the contaminated soil pile with SA2 heavy metal stabilizing agent, and the expert judgment was the pointing judgment from the experts. is a method,
After that, it is divided into 5 equal section depths according to the pile depth, sample cross-sectional images of soil cross-sections at different section depths are acquired using a digital camera, and each sample cross-sectional image is imported into a computer system,
Finally, using Matlab analysis processing software, the sample cross-sectional image in step S2 is digitally processed, and the color difference of the pile components (contaminated soil particles, remediation agent particles) obtained by building a model and calculation method is calculated. Analyzed and calculated, uniformly slicing the digital images with a nine-in-one grid line method, and statistically representing the spot counts and coefficients of variation representing said remedial agent particles in different image sections of each of the two contaminated soil piles, Table 1 below. and shown in Table 2:

Table 1 Comprehensive evaluation of mixing uniformity of contaminated soil piles using SA1 heavy metal stabilizing agent

Table 2 Comprehensive evaluation status of mixing uniformity of contaminated soil using SA2 heavy metal stabilizing agent

As can be seen from the calculated CV arithmetic mean value, the overall evaluation result of the mixing uniformity of the SA1 heavy metal stabilizing agent and the contaminated soil is low variation, and the overall evaluation result of the mixing uniformity of the SA2 heavy metal stabilizing agent and the contaminated soil is low. The evaluation result is medium variation.

Claims (7)

a sleeve pipe (1) and an auger (3), wherein one end of the sleeve pipe (1) is detachably connected to the auger (3);
A handle (2) rotatably connected to the outside of the sleeve pipe (1) is provided, and the handle (2) penetrates the other end of the sleeve pipe (1) via a handle rod (21), and the sleeve A tightening mechanism is provided inside the other end of the pipe (1), said tightening mechanism is provided with a first screw collar (22), a second screw collar (23) and a plurality of sets of tightening lobes (11). ,
The first screw collar (22) and the second screw collar (23) are sequentially fitted on the handle rod (21) from top to bottom, and the connecting base (111) provided on the upper part of the clamping leaf (11). )
are respectively connected to the first threaded collar (22) and the second threaded collar (
23), the connecting rod (24) is connected to the connecting base (111), the first screw collar (22
), rotatably connected to the second screw collar (23),
A thread provided on the handle rod (21) located in the first threaded collar (22)
in the opposite direction to the threads provided on the handle rod (21) located in the second screw collar (23),
auger (3) on said auger (3) at the connection with one end of the sleeve pipe (1)
A plurality of sets of rotary leaves (33) are provided for opening and closing the opening of the rotary leaves (33), and a moving rod (32) is provided at one end of the rotary leaves (33),
A first sliding groove (114) slidably connected to one end of the moving rod (32) and sliding on the other end of the moving rod (32) is provided on the end faces of the clamping leaf (11) and the auger (3). A movably connected second sliding groove (31) is provided respectively, and one end of each of the first sliding groove (114) and the second sliding groove (31) is on the outer wall of the clamping leaf (11). is close to and the other end is close to the inner wall of the clamping leaf (11),
The inside of the clamping leaf (11) is hollow, and the inner wall thereof is provided with a plurality of sets of nail holes (113). is provided with a nail plate (112), said nail plate (112) is slidably connected to the inner bottom surface of the clamping leaf (11),
The nail plate (112) is connected to the inner wall of the clamping leaf (11) through the first spring (1123),
A plurality of sets of nails (1122) are provided on the nail plate (112) for passing through the nail holes (113) in one-to-one correspondence with the nail holes (113),
A limiting slide rail (1125) is provided on the inner bottom surface of the clamping leaf (11) to guide the nail (1122) to fit into the nail hole (113), and the nail plate (112) ,
An apparatus for evaluating mixing uniformity of agents for contaminated soil remediation, characterized in that it is provided with a sliding hole (1124) slidably connected to said limiting slide rail (1125). A limiting base (1121) is provided on the inner bottom surface of the tightening leaf (11) near the outer wall of the tightening leaf (11), and the contact surface of the limiting base (1121) with the moving rod (32) is the first 1 sliding groove (114
) is consistent with the curvature of the soil remediation agent mixing uniformity of claim 1, characterized in that. In said handle rod (21), a limiting groove (
211) is provided. A plurality of sets of sampling boxes (13) are provided on the outer wall of the clamping leaf (11), and the sleeve pipe (1) at a position corresponding to the sampling port of the sampling box (13) is provided with a sampling box (13) 2. Contaminated soil according to claim 1, characterized in that an opening is provided for the passage of the , said opening being provided with a hole cover (12) connected to the sleeve pipe (1) via a torsion spring. Apparatus for evaluating mixing uniformity of restorative agents. the sampling port of the sampling box (13) is higher than the contact surface between the sampling box (13) and the clamping leaf (11), and the contact surface is slidably engaged with the outer wall of the clamping leaf (11); The outer wall of the clamping leaf (11) is provided with a tab (115), and the tab (115) is connected to the bottom end of the sampling box (13) via a third spring (116). An apparatus for evaluating mixing uniformity of a chemical for remediation of contaminated soil according to claim 4. A method of collecting and evaluating samples using the device for contaminated soil remediation assessment chemical mix uniformity of any one of claims 1-5, comprising:
S1: According to the pile shape information, any one of system random, expert judgment, zoning or system pointing is used to determine the sampling points, and the sleeve pipe (1) is placed in the soil at each of the sampling points. By inserting each into the sample and rotating the handle (2), the clamping leaf (11) clamps the soil sample, and the rotating leaf (33) takes out after receiving the soil sample, multi-point sampling of 3-10 sampling points and
S2: Using an image acquisition device to continuously acquire sample cross-sectional images of soil cross-sections at different depths, the file format of the sample cross-sectional images is a file format that can be imported into a computer system, and the image acquisition device is being a digital camera or mobile phone;
S3: A step of performing digital processing on the sample cross-sectional image of step S2 by analysis processing software of the computer system to obtain a digital image that visualizes the color difference of the pile component;
S4: A step of constructing a model and a calculation method, analyzing and calculating the color difference of the pile component obtained in step S3, and obtaining a quantitative evaluation result;
A method for collecting and evaluating samples using a contaminated soil remediation assessment agent mix uniformity device comprising: Specifically, the step S4 is
1) Distinguishing the distribution of contaminated soil particles and remediation agent particles from the digital image based on different colors of pile components, and displaying the contaminated soil particles and remediation agent particles in the form of spots in the digital image;
2) using the gridline method to uniformly slice the digital image in a cross-shaped grid to obtain different image zoning situations;
3) counting the number of spots representing the restorative agent particles within each of the image zonings of step 2);
4) Statistically and analyzing the degree of difference in spot number of repair agent particles between all image zonings, wherein the statistical analysis calculation indicators are the average value and the standard difference;
5) respectively calculating the coefficient of variation of each said sampling point through equation (1) to obtain the uniform distribution of the reparative agent particles;
CV=SD/Mean*100% (1)
where CV is the coefficient of variation of the sampling points, SD is the standard difference, and Mean
is the average value and
6) Summarizing the CV values of each sampling point and averaging the CV values of each sampling point to obtain an arithmetic mean;
1) Based on the arithmetic mean value calculated in step 6), strongly fluctuate if CV value >100%,
Medium fluctuation when CV value is 100% to 40%, low fluctuation when CV value is 40% to 10%, C
Comprehensive evaluation of mixing uniformity of contaminated soil and remediation agent in piles according to the method of weak variation when V value <10%;
7. A method of collecting and evaluating samples using an apparatus for contaminated soil remediation assessment chemical mix uniformity according to claim 6, comprising: