CN114460254A

CN114460254A - Testing device and testing method for hydrogeological parameters of underground water monitoring well

Info

Publication number: CN114460254A
Application number: CN202210119884.7A
Authority: CN
Inventors: 孟娟; 陆宇; 高晴晴; 刘倩; 吕大鹏; 孟国强; 李东林
Original assignee: Fifth Prospecting Team Of Shandong Coal Geology Bureau
Current assignee: Fifth Prospecting Team Of Shandong Coal Geology Bureau
Priority date: 2022-02-09
Filing date: 2022-02-09
Publication date: 2022-05-10
Anticipated expiration: 2042-02-09
Also published as: CN114460254B

Abstract

The invention relates to the technical field of hydrogeology detection, and discloses a testing device and a testing method for hydrogeology parameters of an underground water monitoring well, wherein the testing device for the hydrogeology parameters of the underground water monitoring well comprises a detection box and a circulation groove in the detection box, an electromagnetic valve for sealing one end of the circulation groove is rotationally connected in the circulation groove, a second storage bin and a first storage bin are further symmetrically arranged in the detection box, the circulation groove is used for guiding a water body to the second storage bin and the first storage bin, a partition plate is further arranged in the detection box, a partition plate for detecting the water quality is mounted on the partition plate, and an inclined block is further mounted in the detection box. According to the device, the first rotating rod drives the first stirring blade to rotate, so that the first stirring blade stirs the water body at the second storage bin to flow to the first storage bin, and the device avoids water body precipitation through the stirring of the first stirring blade, so that the possibility of inaccurate detection of the detector is caused.

Description

Testing device and testing method for hydrogeological parameters of underground water monitoring well

Technical Field

The invention relates to the technical field of hydrogeological detection, in particular to a testing device and a testing method for hydrogeological parameters of an underground water monitoring well.

Background

Hydrogeology is a geological branch subject, refers to the phenomenon of various changes and movements of underground water in nature, and mainly researches the distribution and formation rule of the underground water, the physical properties and chemical components of the underground water, the underground water resources and the reasonable utilization thereof, the adverse effects of the underground water on engineering construction and mine exploitation, the prevention and the treatment thereof and the like.

However, because the conventional testing device for the hydrogeological parameters of the underground water monitoring well is only simply put into the ground, water entering the conventional testing device for examination is very easy to precipitate, and the test is accurate, and because the conventional testing device for the hydrogeological parameters of the underground water monitoring well is only used for detecting water in a certain time period, the examination range is small, and errors and other situations are likely to occur.

Disclosure of Invention

The invention provides a testing device and a testing method for hydrogeological parameters of an underground water monitoring well, which have the advantages of large checking range and accurate detection, and solve the problems that the existing testing device for hydrogeological parameters of the underground water monitoring well in the background art is only used for placing the device underground, and water entering the existing testing device for checking is very easy to precipitate, so that the testing is accurate, and the existing testing device for hydrogeological parameters of the underground water monitoring well only detects water in a certain time period, so that the checking range is small, and errors and other conditions are possible to occur.

The invention provides the following technical scheme: the testing device for the hydrogeological parameters of the underground water monitoring well comprises a detection box and a circulation groove in the detection box, wherein an electromagnetic valve used for sealing one end of the circulation groove is rotationally connected in the circulation groove, a second storage bin and a first storage bin are symmetrically arranged in the detection box, the circulation groove is used for guiding water to the second storage bin and the first storage bin, a partition plate is further arranged in the detection box, and a partition plate used for detecting water quality is arranged on the partition plate;

the inside of detection case still installs the sloping block, the inside of detection case still rotates and is connected with first rotary rod, install first stirring leaf on the first rotary rod, first stirring leaf is used for water from second storage storehouse department water conservancy diversion to first storage storehouse department, and through the first rotary rod of internally mounted at the detection case, it is rotatory to utilize first rotary rod to drive first stirring leaf for first stirring leaf stirs the water flow direction first storage storehouse of second storage storehouse department, and the device stirs through first stirring leaf and avoids the water to deposit with this, leads to the detector to appear detecting inaccurate probably.

As an alternative of the testing device for the hydrogeological parameters of the underground water monitoring well, the testing device comprises: a first energy storage bin and a second energy storage bin are symmetrically arranged in the detection box, a first piston plate is connected to the inside of the first energy storage bin in a sliding mode, a first one-way valve is installed on the first piston plate, a second piston plate is connected to the inside of the second energy storage bin in a sliding mode, and a second one-way valve is installed on the second piston plate;

the inside of detection case still the symmetry is provided with first round hole and second round hole, first energy storage storehouse and second storage storehouse intercommunication, second round hole, second energy storage storehouse and first storage storehouse intercommunication, first piston plate is used for extrudeing the inside water in first energy storage storehouse to second storage storehouse department, the water that the second piston plate is used for extracting second round hole department to second energy storage storehouse department, extrudees first energy storage storehouse's inside to first round hole department downwards through first piston plate, erupts by first round hole, and then the water that the water body of second storage storehouse department was mixxed to first round hole injection body to this strengthens the stirring dynamics, lets the inside water impurity of second storage storehouse relatively even, makes things convenient for the detector to detect out accurate data.

As an alternative of the testing device for the hydrogeological parameters of the underground water monitoring well, the testing device comprises: the inside of detection case still installs the second rotary rod, install second stirring leaf on the second rotary rod, the water is stirred in the second stirring leaf, extrudees the water in the left side through first piston plate, utilizes the second piston plate to extract the water on the right side for the water can be followed second storage storehouse department and flowed to first storage storehouse department, forms a circulation, thereby further lets the impurity misce bene in the water, makes things convenient for the detector to detect.

As an alternative of the testing device for the hydrogeological parameters of the underground water monitoring well, the testing device comprises: the first piston plate is provided with a first push rod, the first push rod penetrates through the first energy storage bin and extends into the second energy storage bin, and the first stirring blade is used for extruding the first push rod to slide;

install the second push rod on the second piston board, the second push rod runs through second energy storage storehouse and extends to first energy storage storehouse department, the second stirring leaf is used for contradicting the second push rod and slides, promotes the second piston board through the second push rod and upwards slides, utilizes the second piston board to produce the negative pressure in the inside in second energy storage storehouse to this liquid of extracting first energy storage storehouse department, thereby realizes the automatic up-and-down of first piston board and second piston board.

As an alternative of the testing device for the hydrogeological parameters of the underground water monitoring well, the testing device comprises: the outer surface mounting of first push rod has first spring, first spring is connected with the detection case, first spring is used for driving first push rod and resets, the surface cover of second push rod is equipped with the fourth spring, the fourth spring is connected with the detection case, the fourth spring is used for driving first push rod and resets, through the cooperation of first spring and fourth spring, conveniently drives first push rod and second push rod and resets.

As an alternative of the testing device for the hydrogeological parameters of the underground water monitoring well, the testing device comprises: the water quality detection device is characterized in that a rotating plate is rotatably connected inside the detection box, a torque spring is further installed inside the detection box and connected with the rotating plate, a lug is installed on the rotating plate, an extrusion block is further installed on the electromagnetic valve and used for extruding the lug to move, and the electromagnetic valve is rotated again, so that the extrusion block on the electromagnetic valve extrudes the rotating plate to rotate, water flows into the second storage bin again, and accordingly large-scale water quality detection is achieved.

As an alternative of the testing device for the hydrogeological parameters of the underground water monitoring well, the testing device comprises: the water-saving detection box is characterized in that a first flow storage bin and a second flow storage bin are symmetrically arranged in the detection box, a first through hole is formed in the detection box and communicated with the first flow storage bin, the rotating plate is used for guiding liquid to the first flow storage bin, and water bodies are conveniently stored through the cooperation of the first through hole and the first flow storage bin.

As an alternative of the testing device for the hydrogeological parameters of the underground water monitoring well, the testing device comprises: the inside of detection case is sliding connection still has the L shaped plate, the L shaped plate is used for separating first storage and flows the storehouse and the second storage storehouse of flowing, the inside of detection case still is provided with the second through-hole, the second through-hole is linked together with the second storage storehouse of flowing, the inside of detection case still is provided with first square hole, the inside of second storage storehouse is sliding connection still has the regulating plate, the regulating plate is used for sealed first square hole, be provided with the second square hole on the regulating plate, the third spring is still installed to the inside of detection case, the third spring is connected with the regulating plate, through the cooperation of L shaped plate and regulating plate, conveniently lets liquid flow.

As an alternative of the testing device for the hydrogeological parameters of the underground water monitoring well, the testing device comprises: the adjustable liquid discharge device is characterized in that an inclined plane is arranged on the adjusting plate, the L-shaped plate is used for abutting against the inclined plane, a second spring is further installed inside the detection box and connected with the L-shaped plate, the second spring is used for driving the L-shaped plate to reset, the rotating plate is driven to reset through the torque spring, the second spring pushes the L-shaped plate to reset, the L-shaped plate extrudes the adjusting plate again to slide to the right side, a second square hole in the adjusting plate is communicated with a first square hole, and water coming from the second piston plate can flow into the inside of the circulation groove again through the second square hole, so that automatic liquid discharge is achieved.

The invention also discloses a testing method of the testing device for the hydrogeological parameters of the underground water monitoring well, which comprises the following steps:

s1, placing the detection box underground, enabling the water body to pass through the circulation groove, and when detection is needed, sealing the circulation groove through rotating the electromagnetic valve, enabling the water body to enter the inside of the second storage bin through the rotating plate, and detecting through the detector;

s2, repeatedly opening and closing the circulation groove to enable the water body to enter the second storage bin intermittently, so that large-scale sampling detection of the water body is realized, and the detection accuracy of the detector is improved;

s3, the first rotating rod drives the first stirring blade to rotate and stir the water body in the second storage bin, so that the water body flows from the second storage bin to the first storage bin, and the possibility of inaccurate detection of the detector due to water body precipitation is avoided;

s4, the water body is downwards extruded by the first piston plate, the water body is quickly impacted in the second storage bin, and then the water body at the first storage bin is upwards extracted by the second piston plate, so that the water body continuously rotates and circulates in the detection box, and the detection accuracy of the detector is further improved.

The invention has the following beneficial effects:

1. according to the testing device and the testing method for the hydrogeological parameters of the underground water monitoring well, the first rotary rod is installed inside the detection box, the first rotary rod is used for driving the first stirring blade to rotate, so that the first stirring blade stirs the water at the second storage bin to flow to the first storage bin, and the device prevents the water from precipitating due to the stirring of the first stirring blade, and the possibility that the detector cannot accurately detect the hydrogeological parameters is caused.

2. According to the testing device and the testing method for the hydrogeological parameters of the underground water monitoring well, the second piston plate is utilized to extract the water body on the right side, so that the water body can flow from the second storage bin to the first storage bin to form a circulation, and therefore impurities in the water body are mixed uniformly, and detection by the detector is facilitated.

3. According to the testing device and the testing method for the hydrogeological parameters of the underground water monitoring well, the rotating plate is sealed under the action of the torque spring, after the situation that the rotating plate waits for a period of time, the electromagnetic valve is rotated again, so that the extrusion block on the electromagnetic valve extrudes the rotating plate to rotate, the water body flows into the second storage bin again, and therefore the water body can be inspected on a large scale.

Drawings

Fig. 1 is a schematic structural view of the whole of the present invention.

FIG. 2 is a schematic structural view of the electromagnetic valve and the rotating plate according to the present invention.

FIG. 3 is a cross-sectional view of the detection box of the present invention.

FIG. 4 is a front sectional view of the detection box of the present invention.

FIG. 5 is a schematic view of a portion of the structure of FIG. 4 at C according to the present invention.

FIG. 6 is a schematic view of a portion A of FIG. 2 according to the present invention.

FIG. 7 is a partial structural diagram of FIG. 3 at B according to the present invention.

In the figure: 1. a detection box; 2. a circulation tank; 3. an electromagnetic valve; 4. a rotating plate; 5. a torque spring; 6. a first storage bin; 7. a first through hole; 8. a first storage bin; 9. a first piston plate; 10. a first check valve; 11. a first circular hole; 12. a first push rod; 13. a first spring; 14. a first rotating rod; 15. a first stirring blade; 16. a sloping block; 17. a partition plate; 18. a detector; 19. a first storage bin; 20. a second storage bin; 22. an L-shaped plate; 23. a second spring; 24. a first square hole; 25. an adjusting plate; 26. a third spring; 27. a second square hole; 28. a bevel; 29. a second rotating rod; 30. a second stirring blade; 31. a second push rod; 32. a fourth spring; 35. a second piston plate; 36. a second one-way valve; 37. a second energy storage bin; 38. a second through hole; 39. a second storage bin; 40. a bump; 41. extruding the block; 42. a second circular aperture.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example 1

Referring to fig. 1-3, the embodiment discloses a testing device and a testing method for hydrogeological parameters of an underground water monitoring well, wherein the testing device for hydrogeological parameters of the underground water monitoring well comprises a detection box 1 and a circulation groove 2 in the detection box 1, an electromagnetic valve 3 for sealing one end of the circulation groove 2 is rotatably connected in the circulation groove 2, a second storage bin 20 and a first storage bin 19 are symmetrically arranged in the detection box 1, the circulation groove 2 is used for guiding a water body to the second storage bin 20 and the first storage bin 19, a partition plate 17 is further arranged in the detection box 1, and the partition plate 17 is provided with a partition plate 17 for detecting water quality;

the inside of detection case 1 still installs sloping block 16, and the inside of detection case 1 still rotates and is connected with first rotary rod 14, installs first stirring leaf 15 on the first rotary rod 14, and first stirring leaf 15 is used for leading water conservancy diversion to first storage storehouse 19 department from second storage storehouse 20 department with the water.

Through the first rotary rod 14 of internally mounted at detection box 1, utilize first rotary rod 14 to drive first stirring leaf 15 rotatory for first stirring leaf 15 stirs the water flow direction first storage storehouse 19 of second storage storehouse 20 department, and the device stirs through first stirring leaf 15 with this to avoid the water to deposit, leads to detector 18 to appear detecting inaccurate possibility.

Because the conventional testing device for the hydrogeological parameters of the underground water monitoring well is only put into the ground, and water entering the conventional testing device for examination is very easy to precipitate, the test is accurate, and because the conventional testing device for the hydrogeological parameters of the underground water monitoring well is only used for detecting water in a certain time period, the examination range is small, errors and other situations are possible, the device is provided with a first stirring blade 15 in the detection box 1 for accurately detecting underground water, so that the water is prevented from precipitating;

avoiding precipitation: place detection case 1 in the underground, let the water pass circulation groove 2, when needs detect, through rotary solenoid valve 3, sealed circulation groove 2, make the water pass through the inside that rotor plate 4 got into second storage storehouse 20, detect through detector 18, as shown in fig. 3, through the first rotary rod 14 of internally mounted at detection case 1, it is rotatory to utilize first rotary rod 14 to drive first stirring leaf 15, make first stirring leaf 15 stir the water flow direction first storage storehouse 19 of second storage storehouse 20 department, the device stirs through first stirring leaf 15 with this water of avoiding to deposit, lead to detector 18 to appear detecting inaccurate possibility.

Further, the interior of the first energy storage bin 8 is downwards extruded to the first round hole 11 through the first piston plate 9, and is ejected out of the first round hole 11, and then the water ejected from the first round hole 11 can stir the water at the second storage bin 20, so that the stirring force is increased, and the impurities in the water in the second storage bin 20 are relatively uniform, so that the detector 18 can conveniently detect accurate data;

the inside of detection case 1 still the symmetry be provided with first round hole 11 and second round hole 42, first round hole 11, first energy storage storehouse 8 and second storage storehouse 20 intercommunication, second round hole 42, second energy storage storehouse 37 and first storage storehouse 19 intercommunication, first piston plate 9 is used for extrudeing the inside water in first energy storage storehouse 8 to second storage storehouse 20 department, second piston plate 35 is used for extracting the water in second round hole 42 department to second energy storage storehouse 37 department, the inside of detection case 1 still the symmetry be provided with first storage storehouse 6 and second storage storehouse 39.

Increasing stirring force: as shown in fig. 3, water will first enter the upper end surface of the first piston plate 9 through the first fluid storage chamber 6, since the first piston plate 9 is provided with the first check valve 10, the water body passes through the first check valve 10 into the lower end of the first piston plate 9, and then when the first piston plate 9 slides downward, the first check valve 10 is pressed by the water body at the lower end of the first piston plate 9, so that the first piston plate 9 becomes a sealing body, so that the first piston plate 9 can extrude the water body in the first energy storage bin 8, the first piston plate 9 extrudes the interior of the first energy storage bin 8 downwards to the first round hole 11 and is ejected out of the first round hole 11, the water sprayed by the first round hole 11 can stir the water at the second storage bin 20, so that the stirring force is increased, the impurities in the water in the second storage bin 20 are relatively uniform, and the detector 18 can conveniently detect accurate data;

and (3) circulating suction: according to fig. 3, a second piston plate 35 is further connected to the inside of the second energy storage chamber 37 in a sliding manner, a second check valve 36 mounted on the second piston plate 35 is opposite to the mounting position of the first check valve 10, so that when the second piston plate 35 slides upwards, the second check valve 36 seals the second piston plate 35, when the second piston plate 35 slides upwards, water is sucked from the second circular hole 42 through the second piston plate 35, water is sucked from the first energy storage chamber 19 through the second circular hole 42, and the first piston plate 9 is matched with the second piston plate 35, so that the water is squeezed at the left side by the first piston plate 9, and is sucked at the right side by the second piston plate 35, so that water flows from the second energy storage chamber 20 to the first energy storage chamber 19, and a circulation is formed, thereby further uniformly mixing impurities in the water and facilitating detection by the detector 18.

Further, the water body is extruded on the left side through the first piston plate 9, and the water body is extracted on the right side through the second piston plate 35, so that the water body can flow to the first storage bin 19 from the second storage bin 20 to form a circulation, and further impurities in the water body are uniformly mixed, and the detection of the detector 18 is facilitated, referring to fig. 1-3, a second rotating rod 29 is further installed inside the detection box 1, a second stirring blade 30 is installed on the second rotating rod 29, and the second stirring blade 30 is used for stirring the water body.

And (3) stirring again: according to fig. 3, the second rotating rod 29 is installed at the lower end of the second round hole 42, the second rotating rod 29 drives the second stirring blade 30 to rotate, the second stirring blade 30 stirs the water body to the second round hole 42, the water body is convenient to form a circulation, impurities in the water body are uniformly mixed, and therefore the detection accuracy of the detector 18 is improved.

Further, the second push rod 31 pushes the second piston plate 35 to slide upwards, and negative pressure is generated inside the second energy storage bin 37 by the second piston plate 35, so as to pump the liquid at the position of the first energy storage bin 19, thereby realizing automatic up-and-down sliding of the first piston plate 9 and the second piston plate 35, referring to fig. 1-4, the first push rod 12 is installed on the first piston plate 9, the first push rod 12 penetrates through the first energy storage bin 8 and extends to the inside of the second energy storage bin 20, and the first stirring blade 15 is used for extruding the first push rod 12 to slide;

a second push rod 31 is arranged on the second piston plate 35, the second push rod 31 penetrates through the second energy storage bin 37 and extends to the first energy storage bin 19, and the second stirring blade 30 is used for abutting against the second push rod 31 to slide;

the outer surface mounting of first push rod 12 has first spring 13, and first spring 13 is connected with detection case 1, and first spring 13 is used for driving first push rod 12 and resets, and the surface cover of second push rod 31 is equipped with fourth spring 32, and fourth spring 32 is connected with detection case 1, and fourth spring 32 is used for driving first push rod 12 and resets. The first push rod 12 and the second push rod 31 are driven to reset conveniently through the cooperation of the first spring 13 and the fourth spring 32.

Automatic driving: as shown in fig. 4, when the first rotating rod 14 drives the first stirring blade 15 to rotate, the first stirring blade 15 abuts against the first pushing rod 12 to slide upwards, and then when the first stirring blade 15 does not abut against the first pushing rod 12, the first pushing rod 12 slides downwards, so that the first pushing rod 12 extrudes the water downwards to circulate the water, and the second rotating rod 29 drives the second stirring blade 30 to rotate, the second stirring blade 30 abuts against the second pushing rod 31, so that the second pushing rod 31 is extruded to slide upwards by the second stirring blade 30, the second pushing rod 31 pushes the second piston plate 35 to slide upwards, the second piston plate 35 generates negative pressure inside the second energy storage bin 37, so as to extract the liquid in the first energy storage bin 19, thereby achieving automatic up-and-down sliding of the first piston plate 9 and the second piston plate 35.

Further, by rotating the electromagnetic valve 3 again, the extrusion block 41 on the electromagnetic valve 3 extrudes the rotation plate 4 to rotate, so that the water body flows into the second storage bin 20 again, thereby realizing the large-scale water body inspection, please refer to fig. 1-5, the detection box 1 is also rotatably connected with the rotation plate 4, the detection box 1 is also internally provided with a torque spring 5, the torque spring 5 is connected with the rotation plate 4, the rotation plate 4 is provided with a bump 40, the electromagnetic valve 3 is also provided with the extrusion block 41, and the extrusion block 41 is used for extruding the bump 40 to move.

Detection in an enlarged range: according to fig. 5, when the electromagnetic valve 3 rotates to seal one end of the circulation groove 2, the extrusion block 41 on the electromagnetic valve 3 collides with the protrusion 40, so that the protrusion 40 pushes the rotation plate 4 to open, and then the water enters the inside of the second storage bin 20 through the rotation plate 4 to be detected, and then the electromagnetic valve 3 rotates to open again, so that the rotation plate 4 is sealed under the action of the torque spring 5, after waiting for a period of time, the electromagnetic valve 3 rotates again, so that the extrusion block 41 on the electromagnetic valve 3 extrudes the rotation plate 4 to rotate, and the water flows into the inside of the second storage bin 20 again, thereby realizing the large-scale water body inspection.

Further, the rotating plate 4 is driven to reset by the torque spring 5, the second spring 23 pushes the L-shaped plate 22 to reset, so that the L-shaped plate 22 extrudes the adjusting plate 25 again to slide to the right side, and the second square hole 27 on the adjusting plate 25 is communicated with the first square hole 24, so that water extracted by the second piston plate 35 can flow into the circulation groove 2 again through the second square hole 27, and automatic liquid drainage is realized, referring to fig. 1-7, the detection box 1 is further provided with a first through hole 7, the first through hole 7 is communicated with the first flow storage bin 6, and the rotating plate 4 is used for draining liquid into the first flow storage bin 6;

the detection box 1 is also connected with an L-shaped plate 22 in a sliding manner, the L-shaped plate 22 is used for separating a first flow storage bin 6 from a second flow storage bin 39, a second through hole 38 is further formed in the detection box 1, the second through hole 38 is communicated with the second flow storage bin 39, a first square hole 24 is further formed in the detection box 1, an adjusting plate 25 is further connected in the second flow storage bin 39 in a sliding manner, the adjusting plate 25 is used for sealing the first square hole 24, a second square hole 27 is formed in the adjusting plate 25, a third spring 26 is further mounted in the detection box 1, and the third spring 26 is connected with the adjusting plate 25;

the adjusting plate 25 is provided with an inclined surface 28, the L-shaped plate 22 is used for abutting against the inclined surface 28, a second spring 23 is further installed inside the detection box 1, the second spring 23 is connected with the L-shaped plate 22, and the second spring 23 is used for driving the L-shaped plate 22 to reset.

Automatic liquid drainage: according to fig. 7, when the rotating plate 4 rotates counterclockwise, the rotating plate 4 pulls the L-shaped plate 22 to slide towards the second spring 23, so that the first flow storage chamber 6 is communicated with the second flow storage chamber 39, because the L-shaped plate 22 does not abut against the adjusting plate 25, the adjusting plate 25 is pushed by the third spring 26 to slide towards the left under the action of the third spring 26, so that the adjusting plate 25 seals the first square hole 24, and further, after the second piston plate 35 sucks the water body, the water body enters the first flow storage chamber 6 through the second flow storage chamber 39, so as to realize the circulation of the water body, after the detector 18 detects, the torque spring 5 drives the rotating plate 4 to reset, the second spring 23 pushes the L-shaped plate 22 to reset, so that the L-shaped plate 22 pushes the adjusting plate 25 to slide towards the right again, so that the second square hole 27 on the adjusting plate 25 is communicated with the first square hole 24, and the water body sucked by the second piston plate 35 can flow into the flow channel 2 again through the second square hole 27 And automatic liquid drainage is realized.

Example 2:

the embodiment discloses a testing method of a testing device for hydrogeological parameters of an underground water monitoring well, which comprises the following steps:

s1, placing the detection box 1 underground, enabling the water body to pass through the circulation groove 2, and when detection is needed, sealing the circulation groove 2 through rotating the electromagnetic valve 3, enabling the water body to enter the second storage bin 20 through the rotating plate 4, and detecting through the detector 18;

s2, repeatedly opening and closing the circulation groove 2 to enable the water body to enter the second storage bin 20 intermittently, so that the water body can be sampled and detected in a large range, and the detection accuracy of the detector 18 is improved;

s3, the first rotating rod 14 drives the first stirring blade 15 to rotate and stir the water body in the second storage bin 20, so that the water body flows from the second storage bin 20 to the first storage bin 19, and the possibility of inaccurate detection of the detector 18 due to water body precipitation is avoided;

s4, the water body is extruded downwards by the first piston plate 9, so that the water body is rapidly impacted in the second storage bin 20, and then the water body at the first storage bin 19 is extracted upwards by the second piston plate 35, so that the water body is continuously rotated and circulated in the detection box 1, and the detection accuracy of the detector 18 is further improved.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, various modifications and decorations can be made without departing from the technical principle of the present invention, and these modifications and decorations should also be regarded as the protection scope of the present invention.

Claims

1. Groundwater monitoring well hydrogeological parameter's testing arrangement which characterized in that: the device comprises a detection box (1) and a circulation groove (2) in the detection box (1), wherein the circulation groove (2) is rotationally connected with an electromagnetic valve (3) used for sealing one end of the circulation groove (2), a second storage bin (20) and a first storage bin (19) are symmetrically arranged in the detection box (1), the circulation groove (2) is used for guiding water to the second storage bin (20) and the first storage bin (19), a partition plate (17) is further arranged in the detection box (1), and the partition plate (17) is used for detecting water quality;

an inclined block (16) is further installed inside the detection box (1), a first rotating rod (14) is further rotatably connected inside the detection box (1), a first stirring blade (15) is installed on the first rotating rod (14), and the first stirring blade (15) is used for guiding water from a second storage bin (20) to a first storage bin (19);

a first energy storage bin (8) and a second energy storage bin (37) are further symmetrically arranged inside the detection box (1), a first piston plate (9) is connected inside the first energy storage bin (8) in a sliding mode, a first check valve (10) is installed on the first piston plate (9), a second piston plate (35) is connected inside the second energy storage bin (37) in a sliding mode, and a second check valve (36) is installed on the second piston plate (35);

a first round hole (11) and a second round hole (42) are symmetrically arranged in the detection box (1), the first round hole (11), the first energy storage bin (8) and the second energy storage bin (20) are communicated, the second round hole (42), the second energy storage bin (37) and the first energy storage bin (19) are communicated, the first piston plate (9) is used for extruding water in the first energy storage bin (8) to the second energy storage bin (20), and the second piston plate (35) is used for extracting water in the second round hole (42) to the second energy storage bin (37);

a second rotating rod (29) is further installed inside the detection box (1), a second stirring blade (30) is installed on the second rotating rod (29), the second stirring blade (30) is used for stirring a water body, a first push rod (12) is installed on the first piston plate (9), the first push rod (12) penetrates through the first energy storage bin (8) and extends to the inside of the second energy storage bin (20), and the first stirring blade (15) is used for extruding the first push rod (12) to slide; the second piston plate (35) is provided with a second push rod (31), the second push rod (31) penetrates through the second energy storage bin (37) and extends to the first energy storage bin (19), and the second stirring blade (30) is used for abutting against the second push rod (31) to slide.

2. A groundwater monitoring well hydrogeological parameter testing device as claimed in claim 1, wherein: the outer surface mounting of first push rod (12) has first spring (13), first spring (13) are connected with detection case (1), first spring (13) are used for driving first push rod (12) and reset, the surface cover of second push rod (31) is equipped with fourth spring (32), fourth spring (32) are connected with detection case (1), fourth spring (32) are used for driving first push rod (12) and reset.

3. A test device for hydrogeological parameters of an underground water monitoring well according to claim 1 or 2, characterized in that: the detection box is characterized in that a rotating plate (4) is further rotatably connected inside the detection box (1), a torque spring (5) is further installed inside the detection box (1), the torque spring (5) is connected with the rotating plate (4), a bump (40) is installed on the rotating plate (4), an extrusion block (41) is further installed on the electromagnetic valve (3), and the extrusion block (41) is used for extruding the bump (40) to move.

4. A test device for hydrogeological parameters of an underground water monitoring well according to any of claims 1-3, characterized in that: the liquid drainage detection device is characterized in that a first flow storage bin (6) and a second flow storage bin (39) are symmetrically arranged in the detection box (1), a first through hole (7) is formed in the detection box (1), the first through hole (7) is communicated with the first flow storage bin (6), and the rotating plate (4) is used for draining liquid into the first flow storage bin (6).

5. A test device for hydrogeological parameters of an underground water monitoring well according to any of claims 1-4, characterized in that: the inside of detection case (1) is sliding connection still has L shaped plate (22), L shaped plate (22) are used for separating first storage and flow storehouse (6) and second storage and flow storehouse (39), the inside of detection case (1) still is provided with second through-hole (38), second through-hole (38) are linked together with second storage and flow storehouse (39), the inside of detection case (1) still is provided with first square hole (24), the inside of second storage and flow storehouse (39) is sliding connection still has regulating plate (25), regulating plate (25) are used for sealed first square hole (24), be provided with second square hole (27) on regulating plate (25), third spring (26) are still installed to the inside of detection case (1), third spring (26) are connected with regulating plate (25).

6. A test device for hydrogeological parameters of an underground water monitoring well according to claim 5, which is characterized in that: be provided with inclined plane (28) on regulating plate (25), L shaped plate (22) are used for conflicting inclined plane (28), second spring (23) are still installed to the inside of detection case (1), second spring (23) are connected with L shaped plate (22), second spring (23) are used for driving L shaped plate (22) and reset.

7. A test method of a test device of hydrogeological parameters of an underground water monitoring well according to any of the claims 1-6, characterized by: the method comprises the following steps:

s1, placing the detection box (1) underground, enabling the water body to pass through the circulation groove (2), and sealing the circulation groove (2) through a rotary electromagnetic valve (3) when detection is needed, so that the water body enters the inside of the second storage bin (20) through the rotary plate (4) and is detected through the detector (18);

s2, repeatedly opening and closing the circulation groove (2) to enable the water body to enter the second storage bin (20) intermittently, so that the water body can be sampled in a large range, and the detection accuracy of the detector (18) is improved;

s3, the first rotating rod (14) drives the first stirring blade (15) to rotationally stir the water body in the second storage bin (20), and the water body flows from the second storage bin (20) to the first storage bin (19), so that the water body is prevented from precipitating, and the detector (18) is prevented from having the possibility of inaccurate detection;

s4, the water body is extruded downwards by the first piston plate (9) to quickly impact the inside of the second storage bin (20), and then the water body at the first storage bin (19) is extracted upwards by the second piston plate (35), so that the water body continuously rotates and circulates in the detection box (1), and the detection accuracy of the detector (18) is further improved.