CN113916606A - Water environment sampling and detecting device - Google Patents

Abstract

One or more embodiments of the specification provide a water environment sampling and detecting device, which comprises a mounting plate, a first water storage tank, a water taking assembly, a sampling cylinder, a transfusion assembly, a detecting assembly and a water quality detector, by arranging the mounting plate on the ship body and driving the mounting plate to move to various places in the water area through the ship body, the water in the water area is pumped and conveyed to the first water storage tank through the water taking component, the water in the first water storage tank is pumped into the sampling cylinder through the liquid conveying component, the water quality in the sampling cylinder is detected by the detection component, the detection result is transmitted to the water quality detector for analysis, the water quality data of the water area is directly obtained from the water quality detector after the analysis is finished, therefore, the water quality condition of the whole water area can be directly recorded by an operator, and the problems of complicated whole water area sampling and detecting work, low efficiency and much time consumption are solved.

Description

Water environment sampling and detecting device

Technical Field

One or more embodiments of this description relate to water quality testing technical field, especially relate to a water environment sample and detection device.

Background

Water (chemical formula: H2O) is an inorganic substance composed of two elements of hydrogen and oxygen, and is colorless and odorless transparent liquid at normal temperature and pressure. Water is one of the most common substances on earth, an important resource for all life including human beings, and also the most important component of organisms. People can not keep water in life and production activities, and the quality of drinking water is closely related to the health of people. With the development of social economy, scientific progress and improvement of the living standard of people, the requirements of people on the water quality of drinking water are continuously improved, and the water quality standard of the drinking water is correspondingly continuously developed and improved. Because the formulation of the water quality standard of the drinking water is related to various factors such as living habits, cultures, economic conditions, scientific and technical development level, water resources and the current situation of the water quality of the water resources, and the like of people, the requirements on the water quality of the drinking water are different not only among countries but also among different regions of the same country.

The existing water quality detection method is characterized in that manual collection and test are carried out, the manual collection place is generally arranged at the edge of a water area, the edge of the water area is generally influenced by soil quality, the measured water quality result has great difference, and the water quality in the middle of the water area and other areas is collected by operators who take a boat to collect samples and check the samples, so that the working efficiency is low, the time wasted is more, and the device for carrying out automatic sampling detection on the whole water area is required to be provided.

Disclosure of Invention

In view of the above, one or more embodiments of the present disclosure are directed to provide a method for solving the problems of tedious, inefficient and time-consuming full-water sampling and detection.

In view of the above, one or more embodiments of the present disclosure provide an apparatus for sampling and detecting water environment, comprising:

the top of the mounting plate is provided with a first water storage tank;

the water taking assembly is arranged beside the mounting plate and is connected with the first water storage tank through a pipeline;

the sampling cylinder is arranged on one side of the first water storage tank, and an infusion component is arranged between the sampling cylinder and the first water storage tank;

the detection assembly is arranged at the top of the sampling cylinder;

and the water quality detector is arranged beside the sampling cylinder and electrically connected with the detection assembly.

Preferably, the bottom of the first water storage tank is provided with a second water storage tank, a connecting rod horizontally penetrates through one side, close to each other, of the first water storage tank and the second water storage tank, and two ends of the connecting rod are provided with a disc;

a water pipe is arranged at one position of each disc, which is close to the first water storage tank, one water pipe is connected with the water taking assembly, and the other water pipe is connected with the infusion assembly;

every the disc is close to a department of second storage water tank all is equipped with the dead lever, the dead lever is located the disc is kept away from one side of first storage water tank, every the dead lever all is established through a first support frame hinge on the mounting panel, just every first support frame all with mounting panel fixed connection.

Preferably, the bottom of mounting panel is equipped with the drain tank, the top of drain tank with the mounting panel intercommunication, just the drain tank is located the bottom of second storage water tank, one side of drain tank is equipped with first drain pipe.

Preferably, the side of first storage water tank all is equipped with first lift slip table, every one side that first lift slip table is close to first storage water tank all is equipped with the regulating plate, one of them the regulating plate with the top of first storage water tank offsets, and another the regulating plate with the bottom of second storage water tank offsets.

Preferably, the first water storage tank and the second water storage tank are respectively provided with a limiting block at one side far away from the infusion assembly, one limiting block is positioned at one position of the first water storage tank close to the top, the other limiting block is positioned at one position of the second water storage tank close to the bottom, and the two limiting blocks are positioned in the disc and are symmetrically arranged;

the first support frame is provided with a double-shaft cylinder, an output shaft of the double-shaft cylinder is provided with a limiting clamp plate, and the limiting clamp plate can be sleeved on one limiting block under the pushing of the double-shaft cylinder.

Preferably, the water intake assembly includes:

the second lifting sliding table is arranged at the top of the mounting plate;

the immersible pump sets up on the second lift slip table, the immersible pump is located the mounting panel is kept away from one side of first storage water tank, just the play water end of immersible pump with the water pipe intercommunication.

Preferably, the infusion assembly is a water pump, a water inlet end of the water pump is communicated with the water pipe, and a water outlet end of the water pump is communicated with the sampling cylinder.

Preferably, the sampler barrel is kept away from the one end of water pump is equipped with the second drain pipe, the bottom level of second drain pipe connects and is equipped with the sleeve, telescopic one end is equipped with the unipolar cylinder, be equipped with the piston on the output shaft of unipolar cylinder, the piston sets up in the sleeve.

Preferably, be equipped with drying-machine and temperature-sensing ware on the sampling tube, the drying-machine inlays to be established the top of sampling tube, just temperature-sensing ware wears to establish the top of sampling tube.

Preferably, be equipped with three evenly distributed's circular pipeline between the drying apparatus and the temperature-sensing ware, the detecting component includes:

the second support frame is arranged at the top of the single-shaft cylinder and is fixedly connected with the mounting plate;

the third lifting sliding table is erected at the top of the second supporting frame;

the connecting plate is fixedly arranged on the third lifting sliding table;

the three test tubes are arranged in one-to-one correspondence with the circular pipelines, and each test tube is fixedly connected with the connecting plate and is electrically connected with the water quality detector.

From the above, it can be seen that the water environment sampling and detecting device provided in one or more embodiments of the present disclosure is provided with the mounting plate, the first water storage tank, the water taking assembly, the sampling cylinder, the infusion assembly, the detecting assembly and the water quality detector, wherein the mounting plate is disposed on the ship body, the ship body drives the mounting plate to move to each place of the water area, the water taking assembly pumps water in the water area into the first water storage tank, the infusion assembly pumps water in the first water storage tank into the sampling cylinder, the detecting assembly detects water quality in the sampling cylinder, transmits a detection result to the water quality detector for analysis, and directly obtains data of the water quality in the water area from the water quality detector after analysis is finished, so that an operator directly records the water quality condition of the whole water area, and the problems of complicated sampling and detecting work of the whole water area are solved, low efficiency and much time consumption.

Drawings

In order to more clearly illustrate one or more embodiments or prior art solutions of the present specification, the drawings that are needed in the description of the embodiments or prior art will be briefly described below, and it is obvious that the drawings in the following description are only one or more embodiments of the present specification, and that other drawings may be obtained by those skilled in the art without inventive effort from these drawings.

FIG. 1 is a schematic perspective view of one or more embodiments of the present disclosure;

FIG. 2 is a schematic perspective view of a water intake assembly according to one or more embodiments of the present disclosure;

FIG. 3 is a schematic perspective view of a first water storage tank according to one or more embodiments of the present disclosure;

FIG. 4 is a schematic perspective view of a detection assembly according to one or more embodiments of the present disclosure.

The reference numbers in the figures are:

1-mounting a plate; 11-a drainage tank; 12-a first drain pipe; 13-a first lifting ramp; 14-adjusting plate; 15-a limiting block; 16-a two-axis cylinder; 17-a limit splint;

2-a first water storage tank; 21-a second water storage tank; 22-a connecting rod; 23-a disc; 24-a water pipe; 25-a fixation rod; 26-a first support frame;

3-a water intake assembly; 31-a second lifting slide table; 32-submersible pump;

4-a sampling tube; 41-a water pump; 42-a second drain pipe; 43-a sleeve; 44-single-shaft cylinder; 45-a piston; 46-a dryer; 47-temperature sensor; 48-circular pipes;

5-a detection component; 51-a second support; 52-third ramp; 53-connecting plate; 54-test tube; 6-water quality detector.

Detailed Description

To make the objects, technical solutions and advantages of the present disclosure more apparent, the present disclosure is further described in detail below with reference to specific embodiments.

It is to be noted that unless otherwise defined, technical or scientific terms used in one or more embodiments of the present specification should have the ordinary meaning as understood by those of ordinary skill in the art to which this disclosure belongs. The use of "first," "second," and similar terms in one or more embodiments of the specification is not intended to indicate any order, quantity, or importance, but rather is used to distinguish one element from another. The word "comprising" or "comprises", and the like, means that the element or item listed before the word covers the element or item listed after the word and its equivalents, but does not exclude other elements or items. The terms "connected" or "coupled" and the like are not restricted to physical or mechanical connections, but may include electrical connections, whether direct or indirect. "upper", "lower", "left", "right", and the like are used merely to indicate relative positional relationships, and when the absolute position of the object being described is changed, the relative positional relationships may also be changed accordingly.

Referring to fig. 1 to 4, an apparatus for sampling and detecting water environment includes:

the top of the mounting plate 1 is provided with a first water storage tank 2;

the water taking assembly 3 is arranged beside the mounting plate 1, and the water taking assembly 3 is connected with the first water storage tank 2 through a pipeline;

the sampling cylinder 4 is arranged on one side of the first water storage tank 2, and an infusion component is arranged between the sampling cylinder 4 and the first water storage tank 2;

the detection component 5 is arranged at the top of the sampling tube 4;

and the water quality detector 6 is arranged beside the sampling cylinder 4, and the water quality detector 6 is electrically connected with the detection assembly 5.

By arranging the mounting plate 1, the first water storage tank 2, the water taking component 3, the sampling cylinder 4, the infusion component, the detection component 5 and the water quality detector 6, by arranging the mounting plate 1 on the ship body and driving the mounting plate 1 to move to various places of a water area through the ship body, the water in the water area is pumped and conveyed to the first water storage tank 2 through the water taking component 3, the water in the first water storage tank 2 is pumped into the sampling cylinder 4 through the liquid conveying component, the water quality in the sampling cylinder 4 is detected by the detection component 5, the detection result is transmitted to the water quality detector 6 for analysis, the water quality data of the water area is directly obtained from the water quality detector 6 after the analysis is finished, therefore, an operator can directly record the water quality condition of the whole water area, the problems of tedious whole water area sampling and detecting work, low efficiency and much consumed time are solved, and the problem of conveniently and quickly obtaining the water quality condition of the whole water area is realized.

As an optional embodiment, the bottom of the first water storage tank 2 is provided with a second water storage tank 21, a connecting rod 22 horizontally penetrates through one side of the first water storage tank 2 close to the second water storage tank 21, and two ends of the connecting rod 22 are provided with a disc 23;

a water pipe 24 is arranged at one position of each disc 23 close to the first water storage tank 2, one water pipe 24 is connected with the water taking assembly 3, and the other water pipe 24 is connected with the infusion assembly;

every disc 23 is close to a department of second storage water tank 21 all is equipped with dead lever 25, dead lever 25 is located disc 23 is kept away from one side of first storage water tank 2, every dead lever 25 all establishes through a first support frame 26 hinge on the mounting panel 1, just every first support frame 26 all with mounting panel 1 fixed connection.

For example, in order not to affect the next sampling detection, after the sample detection collected by the first water storage tank 2 is completed, the second water storage tank 21 is rotated from the bottom of the first water storage tank 2 to the top of the first water storage tank 2 by turning over the first water storage tank 2, so that the first water storage tank 2 and the second water storage tank 21 complete the position exchange, the water quality of other water areas is conveyed into the second water storage tank 21 through the water taking assembly 3, so that the residual water quality in the first water storage tank 2 cannot affect the result of the next sampling detection, and after the position exchange between the first water storage tank 2 and the second water storage tank 21, the tank mouth of the first water storage tank 2 faces downwards, so that the residual water quality flows out, the fixing rod 25 is limited by the first supporting frame 26, the disc 23 is limited by the fixing rod 25, so that the disc 23 cannot rotate together with the first water storage tank 2 and the second water storage tank 21, the water pipe 24 is wound and damaged, the problem that detection errors exist when samples are mixed together is solved, and the problem of separate collection and treatment of the samples is realized.

As an alternative embodiment, the bottom of the mounting plate 1 is provided with a drainage tank 11, the top of the drainage tank 11 is communicated with the mounting plate 1, the drainage tank 11 is located at the bottom of the second water storage tank 21, and one side of the drainage tank 11 is provided with a first drainage pipe 12.

For example, in order to prevent that first storage water tank 2 and second storage water tank 21 from when interchanging the position, remaining sample directly pours into mounting panel 1, lead to hull ponding, through bottom installation drain box 11 at mounting panel 1, collect in pouring into drain box 11 through with remaining sample, directly carry the sample to the hull outside through first drain pipe 12, thereby make the hull can not produce the ponding phenomenon, solved on remaining sample directly flows into the hull from mounting panel 1, lead to the hull to have the problem of ponding, the problem of remaining sample in time discharge hull has been realized.

As an optional embodiment, the side of the first water storage tank 2 is provided with a first lifting sliding table 13, and each side of the first lifting sliding table 13 close to the first water storage tank 2 is provided with an adjusting plate 14, wherein one of the adjusting plates 14 abuts against the top of the first water storage tank 2, and the other adjusting plate 14 abuts against the bottom of the second water storage tank 21.

Drive regulating plate 14 through first lift slip table 13 and remove, drive first storage water tank 2 through a regulating plate 14 and remove, drive second storage water tank 21 through another regulating plate 14 and remove to make first storage water tank 2 and second storage water tank 21 accomplish the position automatically and exchange, solved first storage water tank 2 and the problem that the exchange of second storage water tank 21 position needs manual operation, realized the problem of automatic interchange position between first storage water tank 2 and the second storage water tank 21.

As an optional embodiment, the first water storage tank 2 and the second water storage tank 21 are both provided with a limiting block 15 on one side away from the infusion assembly, one limiting block 15 is located at one position of the first water storage tank 2 close to the top, the other limiting block 15 is located at one position of the second water storage tank 21 close to the bottom, and the two limiting blocks 15 are located on the disc 23 and are symmetrically arranged;

the first support frame 26 is provided with a double-shaft cylinder 16, an output shaft of the double-shaft cylinder 16 is provided with a limiting clamp plate 17, and the limiting clamp plate 17 can be sleeved on one limiting block 15 under the pushing of the double-shaft cylinder 16.

For example, due to the mobility of water, the first water storage tank 2 or the second water storage tank 21 can shake when a sample is injected, so that the phenomenon of side turning is caused, the limiting block 15 is installed on the first water storage tank 2 and the second water storage tank 21, and the double-shaft cylinder 16 drives the limiting clamp plate 17 to move and insert on the limiting block 15, so that the first water storage tank 2 or the second water storage tank 21 cannot shake when the sample is injected, the problems of shaking and side turning when the sample is injected into the first water storage tank 2 or the second water storage tank 21 are solved, and the problem of stable work of the first water storage tank 2 and the second water storage tank 21 is solved.

As an alternative embodiment, the water intake assembly 3 comprises:

the second lifting sliding table 31 is arranged at the top of the mounting plate 1;

immersible pump 32 sets up on the second lift slip table 31, immersible pump 32 is located mounting panel 1 is kept away from one side of first storage water tank 2, just immersible pump 32's play water end with water pipe 24 intercommunication.

For example, when the ship body moves to the water area to be measured, the second lifting sliding table 31 drives the submersible pump 4132 to enter the water area to extract a sample to enter the first water storage tank 2 or the second water storage tank 21, and when the ship body moves to the next water area to be measured, the second lifting sliding table 31 drives the submersible pump 32 to move away from the water surface, so that the submersible pump 32 cannot be damaged due to the resistance of water, the problem that the submersible pump 32 is damaged due to the resistance of water in the moving process of the ship body is solved, and the problem that the submersible pump 32 is prevented from being damaged due to the up-and-down lifting of the submersible pump 32 is solved.

As an alternative embodiment, the infusion component is a water pump 41, the water inlet end of the water pump 41 is communicated with the water pipe 24, and the water outlet end of the water pump 41 is communicated with the sampling tube 4.

The water pump 41 drives the samples in the first water storage tank 2 or the second water storage tank 21 to enter the sampling barrel 4, so that the detection component 5 can rapidly detect the samples in the sampling barrel 4, the problem that the samples in the first water storage tank 2 and the second water storage tank 21 flow into the sampling barrel 4 slowly is solved, and the rapid sampling detection is realized.

As an alternative embodiment, a second water discharge pipe 42 is arranged at one end of the sampling cylinder 4 away from the water pump 41, a sleeve 43 is horizontally connected to the bottom of the second water discharge pipe 42, a single-shaft cylinder 44 is arranged at one end of the sleeve 43, a piston 45 is arranged on an output shaft of the single-shaft cylinder 44, and the piston 45 is arranged in the sleeve 43.

Detect the sample of accomplishing in the sampling tube 4 through second drain pipe 42 discharge, thereby make sampling tube 4 collect the sample in other waters fast and detect, when collecting the sample in order to prevent sampling tube 4, the sample directly flows from second drain pipe 42, bottom through at second drain pipe 42 sets up sleeve 43, drive piston 45 through unipolar cylinder 44 and plug up second drain pipe 42, thereby make sampling tube 4 when collecting the sample, the sample can't flow, the very loaded down with trivial details problem of sample in the change process in the sampling tube 4 has been solved, the problem of sampling tube 4 quick replacement sample has been realized.

As an optional embodiment, a dryer 46 and a temperature sensor 47 are arranged on the sampling tube 4, the dryer 46 is embedded in the top of the sampling tube 4, and the temperature sensor 47 is arranged on the top of the sampling tube 4 in a penetrating manner.

For example, when the sample is discharged from the sampling cylinder 4, a residual sample still exists, and a large error is generated when the detection of samples in other water areas is caused, the dryer 46 is installed at the top of the sampling cylinder 4, the interior of the sampling cylinder 4 is dried through the dryer 46, so that the residual sample is evaporated, in order to prevent the dryer 46 from working all the time, the temperature in the sampling cylinder 4 is detected through the temperature sensor 47, when the temperature in the sampling cylinder 4 exceeds a set temperature, the monitoring information is directly transmitted to the dryer 46 through the temperature sensor 47, so that the dryer 46 stops working, so that the dryer 46 is started or closed to operate according to the temperature in the sampling cylinder 4, the problem that the detection of water quality in other water areas is influenced by the residual sample in the sampling cylinder 4 is solved, and the problem that the detection of water quality in other water areas is avoided by drying the residual sample evaporated.

As an alternative embodiment, three circular conduits 48 are disposed between the dryer 46 and the temperature sensor 47, and the detecting assembly 5 includes:

the second support frame 51 is arranged at the top of the single-shaft cylinder 44, and the second support frame 51 is fixedly connected with the mounting plate 1;

a third lifting slide table 52 erected on the top of the second support frame 51;

a connecting plate 53 fixedly arranged on the third lifting sliding table 52;

the three test tubes 54 are arranged in one-to-one correspondence with all the circular pipelines 48, each test tube 54 is fixedly connected with the connecting plate 53, and each test tube 54 is electrically connected with the water quality detector 6.

For example, the three test tubes 54 are respectively used for detecting the ph value, the conductivity and the salinity of water, the third lifting sliding table 52 drives the connecting plate 53 to move downwards, and the connecting plate 53 drives the test tubes 54 to move downwards to the inside of the sampling cylinder 4 through the circular pipeline 48, so that the test tubes 54 transmit detection information to the water quality detector 6 for analysis, the problem that the sample needs to be brought back to a laboratory for operation when the water quality is detected is solved, the rapid sampling and rapid detection are realized, and the data are directly recorded.

Those of ordinary skill in the art will understand that: the discussion of any embodiment above is meant to be exemplary only, and is not intended to intimate that the scope of the disclosure, including the claims, is limited to these examples; within the spirit of the present disclosure, features from the above embodiments or from different embodiments may also be combined, steps may be implemented in any order, and there are many other variations of different aspects of one or more embodiments of the present description as described above, which are not provided in detail for the sake of brevity.

It is intended that the one or more embodiments of the present specification embrace all such alternatives, modifications and variations as fall within the broad scope of the appended claims. Therefore, any omissions, modifications, substitutions, improvements, and the like that may be made without departing from the spirit and principles of one or more embodiments of the present disclosure are intended to be included within the scope of the present disclosure.

Claims (10)

1. A water environment sampling and detecting device is characterized by comprising:

the top of the mounting plate is provided with a first water storage tank;

the water taking assembly is arranged beside the mounting plate and is connected with the first water storage tank through a pipeline;

the sampling cylinder is arranged on one side of the first water storage tank, and an infusion component is arranged between the sampling cylinder and the first water storage tank;

the detection assembly is arranged at the top of the sampling cylinder;

and the water quality detector is arranged beside the sampling cylinder and electrically connected with the detection assembly.

2. The water environment sampling and detecting device according to claim 1, wherein a second water storage tank is arranged at the bottom of the first water storage tank, a connecting rod horizontally penetrates through one side of the first water storage tank, which is close to the second water storage tank, and a disc is arranged at each of two ends of the connecting rod;

a water pipe is arranged at one position of each disc, which is close to the first water storage tank, one water pipe is connected with the water taking assembly, and the other water pipe is connected with the infusion assembly;

every the disc is close to a department of second storage water tank all is equipped with the dead lever, the dead lever is located the disc is kept away from one side of first storage water tank, every the dead lever all is established through a first support frame hinge on the mounting panel, just every first support frame all with mounting panel fixed connection.

3. The water environment sampling and detecting device according to claim 2, wherein a drain tank is arranged at the bottom of the mounting plate, the top of the drain tank is communicated with the mounting plate, the drain tank is arranged at the bottom of the second water storage tank, and a first drain pipe is arranged at one side of the drain tank.

4. The water environment sampling and detecting device according to claim 3, wherein first lifting slide tables are respectively disposed beside the first water storage tank, an adjusting plate is disposed on one side of each first lifting slide table close to the first water storage tank, one of the adjusting plates abuts against the top of the first water storage tank, and the other adjusting plate abuts against the bottom of the second water storage tank.

5. The water environment sampling and detecting device according to claim 4, wherein the first water storage tank and the second water storage tank are provided with limiting blocks at the sides far away from the infusion component, one limiting block is positioned at one position of the first water storage tank close to the top, the other limiting block is positioned at one position of the second water storage tank close to the bottom, and the two limiting blocks are positioned symmetrically on the disc;

the first support frame is provided with a double-shaft cylinder, an output shaft of the double-shaft cylinder is provided with a limiting clamp plate, and the limiting clamp plate can be sleeved on one limiting block under the pushing of the double-shaft cylinder.

6. The apparatus for sampling and testing the aquatic environment according to claim 5, wherein the water intake assembly comprises:

the second lifting sliding table is arranged at the top of the mounting plate;

the immersible pump sets up on the second lift slip table, the immersible pump is located the mounting panel is kept away from one side of first storage water tank, just the play water end of immersible pump with the water pipe intercommunication.

7. The water environment sampling and detecting device of claim 6, wherein the fluid infusion component is a water pump, a water inlet end of the water pump is communicated with the water pipe, and a water outlet end of the water pump is communicated with the sampling cylinder.

8. The water environment sampling and detecting device according to claim 7, wherein a second water discharging pipe is arranged at one end of the sampling cylinder away from the water pump, a sleeve is horizontally connected to the bottom of the second water discharging pipe, a single-shaft cylinder is arranged at one end of the sleeve, a piston is arranged on an output shaft of the single-shaft cylinder, and the piston is arranged in the sleeve.

9. The water environment sampling and detecting device of claim 8, wherein the sampling cylinder is provided with a dryer and a temperature sensor, the dryer is embedded in the top of the sampling cylinder, and the temperature sensor is arranged on the top of the sampling cylinder in a penetrating manner.

10. The water environment sampling and detecting device of claim 9, wherein three evenly distributed circular pipes are arranged between the dryer and the temperature sensor, and the detecting assembly comprises:

the second support frame is arranged at the top of the single-shaft cylinder and is fixedly connected with the mounting plate;

the third lifting sliding table is erected at the top of the second supporting frame;

the connecting plate is fixedly arranged on the third lifting sliding table;

the three test tubes are arranged in one-to-one correspondence with the circular pipelines, and each test tube is fixedly connected with the connecting plate and is electrically connected with the water quality detector.

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