CN215066616U - Water environment monitoring device - Google Patents

Abstract

The utility model relates to a water environment monitoring technology field specifically is a water environment monitoring devices, including the sampler barrel, the bottom fixedly connected with counter weight awl of sampler barrel, the top fixedly connected with lifting rod of sampler barrel, a plurality of slot, a plurality of have been seted up to one side of sampler barrel the inboard of slot is pegged graft and is had the sample box, the edge of sample box is convex, the bevel connection has been seted up at the top of sample box. The utility model has the advantages that: the sampling tube and the sleeve are lifted by the lifting rod, and the sleeve is rotated, so that the sampling box can be pulled out, a plurality of water body samples can be taken out at one time, and the water body samples are water body samples with different depths, so that the water body can be monitored more efficiently and accurately; the setting of bevel connection is also in order to prevent that the water sample from running off, and the sample box is the container that bears the water sample promptly, can directly monitor the use, need not extract the water sample, has simplified the step of sample monitoring, and is more practical.

Description

Water environment monitoring device

Technical Field

The utility model relates to a water environment monitoring technology field, especially a water environment monitoring device.

Background

The water environment refers to the environment of the space where water is formed, distributed and transformed in nature. Refers to the totality of various natural factors and related social factors surrounding the space of people and water bodies which can directly or indirectly influence the life and development of human beings. There are also environments in which natural waters, bounded by land, are located that are relatively stable. The water environment mainly comprises a surface water environment and a groundwater environment. Surface water environments include rivers, lakes, reservoirs, oceans, ponds, marshes, glaciers, and the like, and groundwater environments include spring water, shallow groundwater, deep groundwater, and the like. The water environment is one of the basic elements constituting the environment, is an important place for the survival and development of the human society and is also the field which is most seriously interfered and damaged by human beings. The pollution and destruction of the aqueous environment has become one of the major environmental problems in the world today. In order to obtain real-time data of water resources, sampling and monitoring are often carried out on the water resources.

The existing water resource monitoring device has the following defects:

current water resource monitoring devices need take a sample to the water sample in real time, and the sample quantity that current sampling device once only took out is less, is not convenient for take a sample simultaneously to the water sample of different depths simultaneously.

SUMMERY OF THE UTILITY MODEL

The utility model aims to overcome the shortcoming of prior art, provide a water environment monitoring device.

The purpose of the utility model is realized through the following technical scheme: a water environment monitoring device comprises a sampling cylinder, wherein the bottom of the sampling cylinder is fixedly connected with a counterweight cone, the top of the sampling cylinder is fixedly connected with a lifting rod, one side of the sampling cylinder is provided with a plurality of slots, sampling boxes are inserted into the inner sides of the slots, the edges of the sampling boxes are circular arc-shaped, the top of each sampling box is provided with an oblique opening, the oblique openings are also arranged to prevent water samples from being lost, the sampling boxes are provided with grooves, and the sampling boxes are pulled out from the slots through the grooves;

the surface swing joint of sampling tube has the sleeve, telescopic top fixedly connected with dead lever, the top fixedly connected with swivel of dead lever, telescopic inboard and one side swing joint of sampling box, a plurality of water inlet has been seted up on the sleeve.

Optionally, the counterweight cone is made of stainless steel, and the lifting rod is located on the inner side of the rotating ring.

Optionally, when the sampling tube is lifted from the water through the lifting rod, the sleeve is lifted synchronously, and the plurality of slots can be completely inserted into the sampling box.

Optionally, the outer surface of the sampling box is movably connected with the inner side of the sleeve when the sleeve rotates, and the sampling box is located at different heights of the sampling cylinder through the slot.

Optionally, the sleeve can seal or expose the sampling box when rotating, and the sleeve, the fixed rod and the swivel are of an integrated structure.

Optionally, sleeve, dead lever and swivel synchronous rotation, the swivel sets up above the surface of water, when needs take a sample to the water, only need rotate the swivel above the surface of water to rotate the sleeve.

The utility model has the advantages of it is following:

1. the water environment monitoring device is characterized in that a counterweight cone is fixedly connected to the bottom of a sampling cylinder, a lifting rod is fixedly connected to the top of the sampling cylinder, a plurality of slots are formed in one side of the sampling cylinder, sampling boxes are inserted into the inner sides of the slots, the edge of each sampling box is arc-shaped, an oblique opening is formed in the top of each sampling box, a groove is formed in each sampling box, a sleeve is movably connected to the outer surface of the sampling cylinder, a fixing rod is fixedly connected to the top of each sleeve, a rotating ring is fixedly connected to the top of each fixing rod, the inner side of each sleeve is movably connected with one side of each sampling box, a plurality of water inlets are formed in each sleeve, the sampling cylinder and the sleeves are integrally inserted into water through the counterweight cones, when a water body needs to be sampled, the rotating rings are only required to rotate above the water surface, and the water inlets of the sleeves are rotated to the positions of the sampling boxes, water gets into the sampling box from the bevel connection of sampling box, the sampling box is located different height, thereby take a sample to the water sample of the different degree of depth, the sampling box tightly inserts in the slot, later rotate the sleeve again and seal the sampling box, mention sampling tube and sleeve whole through the lifting rod, rotate the sleeve again, can extract the sampling box, be favorable to once only taking out a plurality of water samples like this, and a plurality of water samples are the water sample of the different degree of depth, be convenient for like this to carry out more high-efficient and accurate monitoring to the water.

2. This water environment monitoring devices, sampling barrel and sleeve pass through the whole aquatic that gets into of counter weight awl, when needs take a sample to the water, only need rotate the change above the surface of water, thereby rotate the sleeve, when telescopic water inlet turned to the position of sampling box, water got into in the sampling box from the bevel connection of sampling box, after sleeve and sampling barrel were wholly mentioned through the lifting rod, can rotate the sleeve once more, thereby open the sampling box, can follow and make the power extract the sampling box through the recess in the slot, the setting of bevel connection is also for preventing the water sample loss, the sampling box is the container that bears the water sample promptly, can directly monitor the use, need not extract the water sample, sampling monitoring's step has been simplified, and is more practical.

Drawings

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

FIG. 2 is a schematic structural view of the sampling tube of the present invention;

fig. 3 is a schematic structural view of the sleeve of the present invention;

fig. 4 is a schematic structural diagram of the sampling box of the present invention;

fig. 5 is a schematic structural view of the slot of the present invention.

In the figure: 1-a sampling cylinder, 2-a counterweight cone, 3-a lifting rod, 4-a slot, 5-a sampling box, 6-a bevel opening, 7-a groove, 8-a sleeve, 9-a fixed rod, 10-a rotary ring and 11-a water inlet.

Detailed Description

The invention will be further described with reference to the accompanying drawings, but the scope of the invention is not limited to the following description.

As shown in fig. 1-5, a water environment monitoring device comprises a sampling tube 1, wherein the bottom of the sampling tube 1 is fixedly connected with a counterweight cone 2, the top of the sampling tube 1 is fixedly connected with a lifting rod 3, one side of the sampling tube 1 is provided with a plurality of slots 4, sampling boxes 5 are inserted into the inner sides of the slots 4, the edges of the sampling boxes 5 are arc-shaped, the top of the sampling boxes 5 is provided with an oblique opening 6, the oblique opening 6 is also arranged to prevent water sample loss, the sampling boxes 5 are provided with grooves 7, and the sampling boxes 5 are forcibly pulled out from the slots 4 through the grooves 7;

the surface swing joint of sampling tube 1 has sleeve 8, and the top fixedly connected with dead lever 9 of sleeve 8, the top fixedly connected with swivel 10 of dead lever 9, sleeve 8's inboard and one side swing joint of sampling box 5 have seted up a plurality of water inlet 11 on the sleeve 8.

As an optimal technical solution of the utility model: the material of counter weight awl 2 is the stainless steel, the lifting rod 3 is located the inboard of swivel 10, sleeve 8 is mentiond in step when the sampling tube 1 is lifted from the aquatic through lifting rod 3, a plurality of slot 4 can insert sampling box 5 completely, the surface of sampling box 5 when sleeve 8 rotates with sleeve 8's inboard swing joint, sampling box 5 is located the different height of sampling tube 1 through slot 4, can seal or expose sampling box 5 when sleeve 8 rotates, sleeve 8, dead lever 9 and swivel 10 structure as an organic whole, sleeve 8, dead lever 9 and swivel 10 rotate in step, swivel 10 sets up more than the surface of water, when needs take a sample to the water, only need rotate swivel 10 more than the surface of water, thereby rotate sleeve 8.

The working process of the utility model is as follows:

s1, the sampling cylinder 1 and the sleeve 8 integrally enter water through the counterweight cone 2, when a water body needs to be sampled, the rotating ring 10 only needs to be rotated above the water surface, so that the sleeve 8 is rotated, when the water inlet 11 of the sleeve 8 is rotated to the position of the sampling box 5, water enters the sampling box 5 from the bevel opening 6 of the sampling box 5, the sampling box 5 is positioned at different heights, so that water body samples with different depths are sampled, and then the sleeve 8 is rotated to seal the sampling box 5;

s2, the sampling tube 1 and the sleeve 8 are lifted integrally through the lifting rod 3, and the sleeve 8 is rotated, so that the sampling box 5 can be pulled out, and the sampling monitoring of the water body is completed.

In summary, when the water environment monitoring device is used, the bottom of the sampling cylinder 1 is fixedly connected with the counterweight cone 2, the top of the sampling cylinder 1 is fixedly connected with the lifting rod 3, one side of the sampling cylinder 1 is provided with a plurality of slots 4, the inner sides of the slots 4 are inserted with the sampling boxes 5, the edge of each sampling box 5 is arc-shaped, the top of each sampling box 5 is provided with an oblique opening 6, the sampling box 5 is provided with a groove 7, the outer surface of the sampling cylinder 1 is movably connected with the sleeve 8, the top of the sleeve 8 is fixedly connected with the fixing rod 9, the top of the fixing rod 9 is fixedly connected with the rotating ring 10, the inner side of the sleeve 8 is movably connected with one side of the sampling box 5, the sleeve 8 is provided with a plurality of water inlets 11, the sampling cylinder 1 and the sleeve 8 integrally enter water through the counterweight cone 2, when a water body needs to be sampled, the rotating ring 10 is only required to be rotated above the water surface, so that the sleeve 8 is rotated, when the water inlet 11 of the sleeve 8 is rotated to the position of the sampling box 5, water enters the sampling box 5 from the bevel opening 6 of the sampling box 5, the sampling box 5 is positioned at different heights, so that water samples at different depths are sampled, the sampling box 5 is tightly inserted into the slot 4, then the sleeve 8 is rotated to seal the sampling box 5, the sampling tube 1 and the sleeve 8 are lifted by the lifting rod 3, and the sleeve 8 is rotated again, so that the sampling box 5 can be pulled out, a plurality of water samples can be taken out at one time, and the water samples are water samples at different depths, so that the water can be monitored more efficiently and accurately; the sampling tube 1 and the sleeve 8 integrally enter water through the counterweight cone 2, when a water body is required to be sampled, the rotating ring 10 only needs to be rotated above the water surface, the sleeve 8 is rotated, when the water inlet 11 of the sleeve 8 is rotated to the position of the sampling box 5, water enters the sampling box 5 from the bevel connection 6 of the sampling box 5, after the sleeve 8 and the sampling tube 1 are integrally lifted through the lifting rod 3, the sleeve 8 can be rotated again, the sampling box 5 is opened, the sampling box 5 can be pulled out from the slot 4 through the groove 7, the bevel connection 6 is also arranged to prevent water sample loss, the sampling box 5 is a container for bearing a water sample, the water sample can be directly monitored and used, the water sample does not need to be extracted, the sampling monitoring step is simplified, and the sampling device is more practical.

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

Claims (6)

1. A water environment monitoring device comprises a sampling cylinder (1), and is characterized in that: the bottom of the sampling tube (1) is fixedly connected with a counterweight cone (2), the top of the sampling tube (1) is fixedly connected with a lifting rod (3), one side of the sampling tube (1) is provided with a plurality of slots (4), sampling boxes (5) are inserted into the inner sides of the slots (4), the edges of the sampling boxes (5) are arc-shaped, the top of each sampling box (5) is provided with an oblique opening (6), and each sampling box (5) is provided with a groove (7);

the surface swing joint of sampling tube (1) has sleeve (8), the top fixedly connected with dead lever (9) of sleeve (8), the top fixedly connected with swivel (10) of dead lever (9), the inboard of sleeve (8) and one side swing joint of sampling box (5), a plurality of water inlet (11) have been seted up on sleeve (8).

2. The water environment monitoring device according to claim 1, wherein: the material of the counterweight cone (2) is stainless steel, and the lifting rod (3) is positioned on the inner side of the rotating ring (10).

3. The water environment monitoring device according to claim 1, wherein: when the sampling tube (1) is lifted from water through the lifting rod (3), the sleeve (8) is lifted synchronously, and the inserting grooves (4) can be inserted into the sampling boxes (5) completely.

4. The water environment monitoring device according to claim 1, wherein: the surface of sampling box (5) when sleeve (8) rotate with the inboard swing joint of sleeve (8), sampling box (5) are located on the different heights of sampling tube (1) through slot (4).

5. The water environment monitoring device according to claim 1, wherein: the sampling box (5) can be sealed or exposed when the sleeve (8) rotates, and the sleeve (8), the fixed rod (9) and the rotating ring (10) are of an integrated structure.

6. The water environment monitoring device according to claim 1, wherein: sleeve (8), dead lever (9) and swivel (10) synchronous revolution, swivel (10) set up above the surface of water, a plurality of water inlet (11) are corresponding with the position of sampling box (5) after sleeve (8) is rotatory.

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