CN220063538U - Sampling device for ecological environment water quality treatment - Google Patents

Abstract

The utility model relates to the technical field of water quality detection, and discloses a sampling device for ecological environment water quality treatment, which solves the problem that multiple sampling is needed when sampling is carried out at different depths, and comprises a first collecting cylinder, wherein the top end of the first collecting cylinder is provided with a top cover, the bottom end of the top cover is provided with a top end sampling mechanism, the bottom end of the first collecting cylinder is provided with a bottom end sampling mechanism, the top end sampling mechanism comprises a bottom rod arranged at the bottom end of the top cover, the outer side of the bottom rod is provided with a spiral blade, and the spiral blade is in threaded connection with the inner wall of the first collecting cylinder; in operation, the magnetism of the top cover is the same as that of the magnetic blocks, so that when the first collecting cylinder is placed in water, the floating blocks drive the top cover to move upwards, repulsive force borne by the magnetic blocks is reduced, the magnetic blocks move upwards under the action of the springs, the first collecting cylinder and the second collecting cylinder can feed water together, water samples with different depths are collected simultaneously, and working efficiency is improved.

Description

Sampling device for ecological environment water quality treatment

Technical Field

The utility model belongs to the technical field of water quality detection, and particularly relates to a sampling device for ecological environment water quality treatment.

Background

With the development of social economy, environmental pollution is more and more serious, in order to ensure the safety of drinking water, water quality monitoring of a water source is an important content, at present, a water quality monitoring sampling device is generally required in the water quality monitoring process, and the water quality is detected by sampling, collecting and carrying out subsequent water quality detection analysis so as to formulate rescue measures for the water quality, and according to the patent document with the authorized bulletin number of CN216717918U, the utility model is named as a sampling device for ecological environment, and the description of the patent document is as follows: through setting up the water pump for cooperation inlet tube and outlet pipe are with the inner chamber of outside water source output to the bin, have played the advantage that improves sampling efficiency, through setting up the locating plate, be used for fixing the motor, through setting up the motor, be used for driving and connect bull stick and stirring leaf and rotate, the water source after the fixed plate inner chamber sampling stirs, the water source after avoiding the sampling deposits for a long time, impurity in the water source appears depositing, lead to appearing detecting inaccurate condition when detecting water quality testing, through setting up draw box and connecting pipe, be used for the valve on cooperation connecting pipe surface to export the inner chamber of draw the bin with the water source after the stirring of fixed plate inner chamber, the staff of being convenient for draws the water source after gathering, but still have following defect:

because the water quality of different depths may have different, when sampling the water of different depths at present, the sampling needs to be carried out for a plurality of times, which is troublesome.

Disclosure of Invention

Aiming at the situation, in order to overcome the defects of the prior art, the utility model provides the sampling device for the ecological environment water quality treatment, which effectively solves the problem that multiple times of sampling are needed when sampling is carried out at different depths.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the sampling device for ecological environment water quality treatment comprises a first collecting cylinder, wherein a top cover is arranged at the top end of the first collecting cylinder, a top end sampling mechanism is arranged at the bottom end of the top cover, and a bottom end sampling mechanism is arranged at the bottom end of the first collecting cylinder;

the top sampling mechanism comprises a bottom rod arranged at the bottom end of the top cover, a spiral blade is arranged at the outer side of the bottom rod and is in threaded connection with the inner wall of the first collecting cylinder, a connecting rod is further arranged at the bottom end of the top cover at equal angles, stirring blades are arranged at one side of the connecting rod at equal intervals, a floating block is arranged at the top end of the top cover, a bottom block is arranged at the bottom end of the bottom rod, communication holes are formed at the top end of the bottom block at equal angles, the diameter of the bottom block is larger than the diameter of a cylinder opening of the first collecting cylinder, and the diameter of the top cover is larger than the diameter of the first collecting cylinder;

the bottom sampling mechanism comprises a bottom groove arranged at the bottom end of the first collecting cylinder, a spring is arranged in the bottom groove, a magnetic block is arranged at the bottom end of the spring, a water inlet hole is formed in the outer side of the bottom groove at equal angles, a second collecting cylinder is connected with the bottom end of the bottom groove in a threaded manner, and a bottom cone is arranged at the bottom end of the second collecting cylinder.

Preferably, the magnetic block and the water inlet hole are positioned on the same horizontal line, the outer side of the magnetic block is clung to the water inlet hole, and the magnetism of the magnetic block is the same as that of the top cover.

Preferably, the stirring blade at the top end is flush with the top end of the first collecting cylinder, and the stirring blade at the bottom end and the water inlet hole are on the same horizontal line.

Compared with the prior art, the utility model has the beneficial effects that:

1) In operation, the magnetism of the top cover is the same as that of the magnetic block, so that when the first collecting cylinder is placed in water, the floating block drives the top cover to move upwards, the repulsive force borne by the magnetic block is reduced, the magnetic block moves upwards under the action of the spring, the first collecting cylinder and the second collecting cylinder are enabled to feed water together, water samples with different depths are collected simultaneously, and the working efficiency is improved;

2) In operation, through the top and the first cylinder threaded connection of top cap that sets up, at the top cap rebound in-process for the top cap rotates, makes stirring leaf rotate then, and near the first cylinder top of stirring She Weiyu and inlet opening, thereby drives water misce bene around when rotating, thereby improves the accuracy that the water sample was collected.

Drawings

The accompanying drawings are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this specification, illustrate the utility model and together with the embodiments of the utility model, serve to explain the utility model.

In the drawings:

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a schematic view of the internal structure of the first collecting cylinder according to the present utility model;

FIG. 3 is a schematic view of a first cartridge of the present utility model;

FIG. 4 is a schematic diagram of a top sampling mechanism according to the present utility model;

fig. 5 is a schematic view of the second collecting barrel according to the present utility model.

In the figure: 1. a first collection canister; 2. a top cover; 3. a top sampling mechanism; 301. a bottom bar; 302. a helical blade; 303. a bottom block; 304. a connecting rod; 305. stirring the leaves; 306. a floating block; 307. a communication hole; 4. a bottom sampling mechanism; 401. a bottom groove; 402. a water inlet hole; 403. a spring; 404. a magnetic block; 405. a second collection cylinder; 406. a bottom cone.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the utility model; all other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

An embodiment I is shown in fig. 1-5, the utility model comprises a first collecting cylinder 1, a top cover 2 is arranged at the top end of the first collecting cylinder 1, a top end sampling mechanism 3 is arranged at the bottom end of the top cover 2, and a bottom end sampling mechanism 4 is arranged at the bottom end of the first collecting cylinder 1.

In the second embodiment, based on the first embodiment, the top sampling mechanism 3 includes a bottom rod 301 installed at the bottom end of the top cover 2, a spiral blade 302 is installed at the outer side of the bottom rod 301, the spiral blade 302 is in threaded connection with the inner wall of the first collecting cylinder 1, a connecting rod 304 is installed at the bottom end of the top cover 2 at equal angles, stirring blades 305 are installed at one side of the connecting rod 304 at equal intervals, a floating block 306 is installed at the top end of the top cover 2, a bottom block 303 is installed at the bottom end of the bottom rod 301, communication holes 307 are formed at the top end of the bottom block 303 at equal angles, the diameter of the bottom block 303 is larger than the diameter of a cylinder mouth of the first collecting cylinder 1, and the diameter of the top cover 2 is larger than the diameter of the first collecting cylinder 1;

the second collecting cylinder 405 is fixed, when the floating block 306 enters into water, the floating block 306 moves upwards under the buoyancy of the water at this time, and the floating block 306 is fixedly connected with the top cover 2, so that the top cover 2 moves upwards, the helical blade 302 at the bottom end of the top cover 2 is in threaded connection with the first collecting cylinder 1, at this time, the top cover 2 moves upwards, so that the helical blade 302 rotates out of the thread, and then the top cover 2 is driven to rotate, so that the top cover 2 continuously rotates in the upward moving process, at this time, the top cover 2 rises upwards, so that the top end of the first collecting cylinder 1 is opened, so that water near the top end of the first collecting cylinder 1 enters into the first collecting cylinder 1, and the collection of upper water samples is completed.

In the third embodiment, based on the second embodiment, the bottom sampling mechanism 4 includes a bottom groove 401 opened at the bottom end of the first collecting cylinder 1, a spring 403 is installed in the bottom groove 401, a magnetic block 404 is installed at the bottom end of the spring 403, a water inlet hole 402 is opened at an equal angle on the outer side of the bottom groove 401, a second collecting cylinder 405 is connected at the bottom end of the bottom groove 401 in a threaded manner, a bottom cone 406 is installed at the bottom end of the second collecting cylinder 405, the magnetic block 404 and the water inlet hole 402 are positioned on the same horizontal line, the outer side of the magnetic block 404 is tightly attached to the water inlet hole 402, the magnetism of the magnetic block 404 is the same as that of the top cover 2, a stirring blade 305 at the top end is flush with the top end of the first collecting cylinder 1, and the stirring blade 305 at the bottom end is on the same horizontal line as the water inlet hole 402;

in the upward moving process of the top cover 2, as the magnetic blocks 404 and the top cover 2 have the same magnetism, the magnetic blocks 404 are subjected to the repulsive force of the top cover 2, when the top cover 2 moves upward, and the distance between the magnetic blocks 404 and the top cover 2 is increased, the magnetic blocks 404 move upward under the action of the springs 403, so that the magnetic blocks 404 come above the water inlet holes 402, and at the moment, the outside of the second collecting cylinder 405 and the inside of the second collecting cylinder 405 are communicated through the water inlet holes 402, so that water at the bottom enters the inside of the second collecting cylinder 405 from the water inlet holes 402, and collection of water samples at the lower layer is completed;

in the process of upward movement and rotation of the top cover 2, the stirring blade 305 is fixedly connected with the top cover 2 through the connecting rod 304, so that the top cover 2 rotates to drive the stirring blade 305 to rotate, and water near the water inlet 402 near the top end of the first collecting cylinder 1 is stirred, so that substances in the water and the water are uniformly stirred and enter the first collecting cylinder 1 and the second collecting cylinder 405, and the accuracy of water sample collection is improved.

Working principle: when the device works, the second collecting cylinder 405 and the bottom groove 401 are screwed up, the bottom cone 406 is inserted into water to be sampled, the second collecting cylinder 405 is vertical to the water surface, the second collecting cylinder 405 is fixed, when the floating block 306 enters into the water, the floating block 306 moves upwards under the buoyancy of the water, the floating block 306 is fixedly connected with the top cover 2, so that the top cover 2 is carried to move upwards, the spiral blade 302 at the bottom end of the top cover 2 is in threaded connection with the first collecting cylinder 1, the top cover 2 moves upwards, so that the spiral blade 302 rotates out of the threads, then the top cover 2 is driven to rotate, the top cover 2 is continuously rotated in the upward moving process, at the moment, the top cover 2 is lifted upwards, so that the top end of the first collecting cylinder 1 is opened, the water near the top end of the first collecting cylinder 1 enters into the first collecting cylinder 1, and when the top cover 2 moves upwards, the magnetic block 404 and the top cover 2 have the same magnetism, so that the magnetic block 404 is subjected to the repulsive force of the top cover 2, when the top cover 2 moves upwards, so that the distance between the magnetic block 404 and the top cover 2 increases, at this time, the magnetic block 404 moves upwards under the action of the spring 403, so that the magnetic block 404 comes above the water inlet 402, at this time, the outside of the second collecting cylinder 405 is communicated with the inside of the second collecting cylinder 405 through the water inlet 402, so that the water at the bottom enters the inside of the second collecting cylinder 405 from the water inlet 402, and when the top cover 2 moves upwards and rotates, as the stirring blade 305 is fixedly connected with the top cover 2 through the connecting rod 304, the top cover 2 rotates to drive the stirring blade 305 to rotate, so that the water near the water inlet 402 near the top end of the first collecting cylinder 1 is stirred evenly, so that the substances therein stir with the water and enter the inside of the first collecting cylinder 1 and the second collecting cylinder 405, after the water sample is collected, take out the second collecting vessel 405, the floating block 306 breaks away from the surface of water this moment, and top cap 2 moves down under self gravity effect, closes first collecting vessel 1 top, and simultaneously when top cap 2 moves down, magnetic path 404 receives the repulsion and increases to make magnetic path 404 move down and reclose inlet opening 402, take out the back, upwards rotate top cap 2, then pour out the water sample that collects in first collecting vessel 1 and the second collecting vessel 405 and detect.

It is noted that relational terms such as first and second, and the like are 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. Moreover, 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.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (3)

1. The utility model provides a sampling device for ecological environment water quality treatment, includes first collection cylinder (1), its characterized in that: a top cover (2) is arranged at the top end of the first collecting cylinder (1), a top end sampling mechanism (3) is arranged at the bottom end of the top cover (2), and a bottom end sampling mechanism (4) is arranged at the bottom end of the first collecting cylinder (1);

the top sampling mechanism (3) comprises a bottom rod (301) arranged at the bottom end of the top cover (2), a spiral blade (302) is arranged on the outer side of the bottom rod (301), the spiral blade (302) is in threaded connection with the inner wall of the first collecting cylinder (1), a connecting rod (304) is further arranged at the bottom end of the top cover (2) at equal angles, stirring blades (305) are equidistantly arranged on one side of the connecting rod (304), a floating block (306) is arranged at the top end of the top cover (2), a bottom block (303) is arranged at the bottom end of the bottom rod (301), communication holes (307) are formed in the top end of the bottom block (303) at equal angles, the diameter of the bottom block (303) is larger than the diameter of a cylinder mouth of the first collecting cylinder (1), and the diameter of the top cover (2) is larger than the diameter of the first collecting cylinder (1);

the bottom sampling mechanism (4) comprises a bottom groove (401) formed in the bottom end of the first collecting barrel (1), a spring (403) is arranged in the bottom groove (401), a magnetic block (404) is arranged at the bottom end of the spring (403), a water inlet hole (402) is formed in the outer side of the bottom groove (401) at equal angles, a second collecting barrel (405) is connected with the bottom end of the bottom groove (401) in a threaded mode, and a bottom cone (406) is arranged at the bottom end of the second collecting barrel (405).

2. The sampling device for ecological environment water treatment according to claim 1, wherein: the magnetic block (404) and the water inlet hole (402) are positioned on the same horizontal line, the outer side of the magnetic block (404) is tightly attached to the water inlet hole (402), and the magnetism of the magnetic block (404) is the same as that of the top cover (2).

3. The sampling device for ecological environment water treatment according to claim 1, wherein: the stirring blades (305) at the top end are flush with the top end of the first collecting cylinder (1), and the stirring blades (305) at the bottom end and the water inlet holes (402) are on the same horizontal line.