CN213427878U - Benthos sampling device - Google Patents

Abstract

The utility model relates to a benthos sampling device, including ration portion and collection portion, set up sediment agitating unit in the ration portion, ration portion includes cubic's main part, air pump and trachea, penetrating around the main part, the collection portion with the back of main part communicates, the main part two sides of main part are provided with the baffle, and the opening of bottom for having known area, the air pump sets up in the main part, tracheal one end with the air pump intercommunication, the other end sets up the bottom of main part. Through above device, the user puts into the water with benthos sampling device, opens the air pump and can stir the bottom material, need not artifical stirring to the stirring of bottom material is more even than artifical stirring.

Description

Benthos sampling device

Technical Field

The utility model relates to a water environment monitoring field, more particularly relates to a benthos sampling device.

Background

In the environmental monitoring of natural water bodies such as lakes, rivers and the like, benthos is one of important monitoring indexes reflecting water quality changes. Benthos is an important component of water ecosystem, and plays an important role in ecological systems such as lakes and rivers. As a decomposer, the benthos can promote the decomposition and metabolism of underwater organic debris and accelerate the energy flow of the substances in the ecological system. If the water body is lack of benthos, bacteria and algae are easy to breed, and black and odorous water or water bloom polluted water body and the like are formed. In addition, some benthic organisms are sensitive to some contaminants or nutrients for their growth and reproduction. Therefore, the benthos becomes an ideal natural detector and can be used for evaluating water quality, monitoring pollution and reflecting the quality condition of a water body.

Sorber nets are a common benthos sampling device. As shown in FIG. 1, the conventional Sorbet net is relatively simple and is divided into two portions, a dosing block and a collection net connected to the rear of the dosing block. During sampling, the quantitative frame is towards the upstream of water flow, stirring is carried out in the range defined by the quantitative frame, and benthos is collected in the net bag of the collecting net under the action of the water flow. The suo bo net is suitable for water bodies with sediment such as silt, gravel, pebbles and the like. However, this device requires manual agitation of the substrate sludge and, for some substrates with stones, scrubbing of the stones to obtain benthic organisms attached to the stones. This process is time consuming and laborious, and therefore, a new sampling device for collecting benthic organisms is required.

SUMMERY OF THE UTILITY MODEL

In order to solve the problems, the utility model provides a benthos sampling device, which comprises a quantitative part and a collecting part, wherein a bottom mud stirring device is arranged in the quantitative part.

In a specific embodiment, the quantifying part comprises a cube-shaped main body, an air pump and an air pipe, the main body is through from front to back, the collecting part is communicated with the back of the main body, two sides of the main body are provided with baffles, the bottom of the main body is an opening with a known area, the air pump is arranged on the main body, one end of the air pipe is communicated with the air pump, and the other end of the air pipe is arranged at the bottom of the main body.

Through above device, the user puts into the water with benthos sampling device, opens the air pump and can stir the bottom material, need not artifical stirring to the stirring of bottom material is more even than artifical stirring.

In a specific embodiment, a supporting part is provided on the top of the main body, and the air pump is provided on the supporting part.

In a particular embodiment, the benthic organism sampling apparatus comprises a plurality of said air tubes, a majority of said air tubes being disposed on a baffle on a side of said body, the bottom opening facing the vertical baffle.

In a preferred embodiment, the benthic organism sampling apparatus further comprises a motor, a connecting rod, an air outlet pipe, a flushing disc, bristles, and a T-shaped connecting pipe, the T-shaped connecting pipe being in communication with the air pipe;

the motor is arranged on the main body, the brush bristles are arranged below the bottom surface of the flushing disc, the air outlet pipe is connected with the flushing disc and penetrates through the flushing disc, and air outlet holes are formed in the part below the bottom surface of the flushing disc;

the motor is fixedly connected with the top end of the air outlet pipe through a connecting rod, the T-shaped connecting pipe is clamped between the bottom end of the connecting rod and the top end of the air outlet pipe, and the T-shaped connecting pipe is communicated with the air outlet pipe.

The above improvements provide a benthic organism sampling device having a wider range of applications, both for soft substrates and for harder substrates, such as substrates with larger cobblestones or stones. The brush hair not only can stir softer bottom material, can scrape harder bottom material moreover and get, consequently stir more abundant to bottom material and water for the sampling is more complete.

In a specific embodiment, the air outlet pipe is a hollow T-shaped pipe, the upper part of the air outlet pipe is a vertical section, the lower part of the air outlet pipe is a horizontal section, the horizontal section is connected with the air outlet pipe of the flushing disc, the vertical section penetrates through the flushing disc, and the top end of the vertical section is positioned above the flushing disc. The horizontal section of the air outlet pipe is provided with a plurality of air outlet holes, and the air outlet holes can cover all areas or most areas of the whole sampling area along with the rotation of the air outlet pipe driven by the motor.

In a preferred embodiment, the bottom opening of the main body of the dosing section is circular, the size of the flushing disc is matched with that of the bottom opening of the main body of the dosing section, so that the bristles cover the whole bottom surface, the length of the horizontal section of the air outlet pipe is the same as the diameter of the flushing disc, and the horizontal section of the air outlet pipe is provided with a plurality of air outlet holes along the length direction, so that the air outlet holes can cover the whole sampling area in the rotation process.

In a preferred embodiment, the bottom of the horizontal section of the air outlet pipe is positioned higher than the bottoms of the bristles. This setting prevents that the outlet duct horizontal segment from being worn and torn in the sampling process.

In a specific embodiment, the top end of the connecting rod is connected with the motor, the bottom end of the connecting rod extends out of the small-diameter connecting section, the small-diameter connecting section penetrates through the connecting T-shaped pipe, and the tail end of the connecting T-shaped pipe is connected with the top end of the air outlet pipe.

Preferably, a connecting assembly with the diameter smaller than the inner diameter of the air outlet pipe is arranged in the pipe orifice at the top end of the air outlet pipe, and the tail end of the small-diameter connecting section of the connecting rod is connected with the connecting assembly. Through the arrangement, the T-shaped connecting pipe can be clamped between the bottom end of the connecting rod and the top end of the air outlet pipe, and the T-shaped connecting pipe is communicated with the air outlet pipe.

In a particular embodiment, the small diameter connecting section is connected with the connecting assembly by a thread or a snap connection.

Drawings

FIG. 1 is a schematic representation of a prior art Sorbet mesh;

fig. 2 is a schematic view of a first embodiment of the present invention;

FIG. 3 is a schematic view of a quantitative section according to a first embodiment of the present invention;

FIG. 4 is a schematic view of a quantitative section according to a second embodiment of the present invention;

FIG. 5 is a drawing showing the intention of an air pump, a motor, an air outlet pipe and a brush plate according to a second embodiment of the present invention;

FIG. 6 is a schematic view of a connecting rod, a T-shaped connecting tube and an air outlet tube according to a second embodiment of the present invention;

fig. 7 is a bottom view of the flush plate.

In the drawings, the components represented by the respective reference numerals are listed below:

1. the quantitative part comprises a quantitative part 11, a main body 12, an air pump 13, an air pipe 14, a motor 15, a connecting rod 151, a small-diameter connecting section 16, an air outlet pipe 161, a vertical section 1611, a connecting assembly 162, a horizontal section 1621, a connecting part 1622, an air outlet hole 17, a flushing disc 171, a brushing area 172 and an air outlet pipe connecting area; 173. through holes 18, bristles 19, T-shaped connecting pipes 2, a collecting part 21, a collecting tank 22 and a water permeable net.

Detailed Description

The principles and features of the present invention are described below in conjunction with the following drawings, the examples given are only intended to illustrate the present invention and are not intended to limit the scope of the present invention.

Example 1

The utility model discloses a benthos sampling device of first embodiment is as shown in fig. 2 and 3, including ration portion 1 and collection portion 2, set up sediment disturbance device in the ration portion 1, ration portion includes cubic's main part 11, air pump 12 and many trachea 13, penetrating around the main part 11, at the back with collection portion 2 intercommunication, main part 11 two sides of main part 11 are provided with the baffle, and the opening of bottom for having known area, main part 11 top are provided with supporting part 14, air pump 12 sets up on supporting part 14, trachea 13 one end with air pump 12 intercommunication, the other end sets up the bottom of main part 11. The air tube 13 is mostly arranged on a baffle on the side of the main body 11, and the opening at the bottom faces the vertical baffle.

The collecting part 2 comprises a water permeable net 22 and a collecting tank 21, two ends of the water permeable net 22 are opened, one end of the water permeable net is communicated with the back of the quantifying part main body 11, and the other end of the water permeable net is detachably connected with the collecting tank 21. Preferably, the openings through which the water permeable net 21 is connected to the collection tank 22 are small.

When the device is used, the bottom surface of the main body 11 is placed at the sampling position, the front surface faces the direction of incoming water, then the air pump 12 is started, the air outlet of the air pipe 13 sprays air bubbles to disturb the sediment, so that benthos are dispersed in the water along with the sediment and enter the collecting tank 22 along with the water flow. After collection is complete, the collection tank 22 is removed and replaced with a new collection tank for sampling at the next sampling point.

Example 2

We have modified the stirring device based on the design concept of the first embodiment to obtain the second embodiment. A second embodiment of the invention is shown in fig. 4-7. In this embodiment, the collecting part 2 and the main body 11 of the dosing part are similar to the above embodiments. Except that the present embodiment provides a scouring assembly adapted to more substrate and to more thoroughly agitate the substrate.

The scouring component comprises an air pump 12, an air pipe 13, a motor 14, an air outlet pipe 16, a scouring disc 17 and bristles 18. The air pump 12 is connected with the air pipe 13, the air pipe 13 is communicated with the air outlet pipe 16 through a T-shaped connecting pipe 19, the motor 14 is connected with the air outlet pipe 16 through a connecting rod 15, the air outlet pipe 16 is a hollow T-shaped pipe, the upper portion is a vertical section 161, and the lower portion is a horizontal section 162. The bottom surface of the flushing plate 17 is provided with a bristle connection region 171 and an air outlet tube connection region 172. The bristle connecting area 171 is provided with bristles 18, the horizontal section 162 of the outlet pipe 16 is connected with the outlet pipe connecting area 172 of the flushing disk 17, the vertical section 161 passes through a through hole 173 on the flushing disk 17 to reach the upper part of the flushing disk 17, and the top part is communicated with the T-shaped connecting pipe 19 and is connected with the connecting rod 15. An air hole 1622 is formed on the horizontal section 162 of the outlet pipe 16. The bottom of the air outlet tube 16 is higher than the bristles. The upper and lower mouths of the T-shaped connecting pipe 19 are opposite and face to the vertical direction, and the middle mouth of the T-shaped connecting pipe faces to the horizontal direction.

When the device is used, the bottom surface of the main body 11 is placed at a sampling position, the front surface faces the direction of incoming water, then the air pump 12 and the motor 14 are started, the motor 14 drives the air outlet pipe 16 to rotate through the connecting rod 15, the air outlet pipe 16 drives the flushing disc 17 to rotate, so that bristles on the flushing disc 17 rub with a substrate, and adhered substances on the substrate are brushed down. The air pump 12 pumps air to the air outlet pipe 16 through the air pipe 13, and the air comes out from the air holes on the horizontal section 162 of the air outlet pipe 16 to disturb the substrate and the water body. The benthic organisms are dispersed in the water with the sediment and enter the collection tank 22 with the water flow. After collection is complete, the collection tank 22 is removed and replaced with a new collection tank for sampling at the next sampling point.

The device of this embodiment is more widely applicable and can be used on soft substrates as well as harder substrates, such as substrates with larger cobbles or stones. And, the device of this embodiment of use still can stir bottom material and water more fully for the sample is more complete.

In order to illustrate the present embodiment more clearly, we further refine the component structure and the connection features in the following, which are merely for illustrative purposes and should not limit the scope of protection of the present invention.

In one embodiment, to make the connection between the air pipe 13, the T-shaped connecting pipe 19, the connecting rod 15 and the air outlet pipe 16 effective, we proceed with the following arrangement. The pipe diameter of the T-shaped connecting pipe 19 is the same as that of the air outlet pipe 16, the upper end of the connecting rod 15 is connected with the motor 14, the diameter of the lower end of the connecting rod is larger than or equal to that of the T-shaped connecting pipe 19, and the top of the T-shaped connecting pipe 19 can be blocked to form air-tight connection. The lower end of the connecting rod 15 extends out of the small-diameter connecting section 151 with a diameter smaller than that of the T-shaped connecting pipe 19, a connecting assembly 1611 is arranged in the top pipe orifice of the vertical section 161 of the air outlet pipe 16, and the outer diameter of the connecting assembly 1611 is smaller than the inner diameter of the air outlet pipe 16. The small diameter connecting section 151 passes through the upper and lower orifices of the T-shaped connecting pipe 19, extends into the vertical section 161 of the outlet pipe 16, and is connected to the connecting member 1611. Thus, the air pipe 13 is communicated with the air outlet pipe 16, and the motor drives the air outlet pipe 16 to rotate while the air pipe 13 is still. The junction of the top of T shape connecting pipe 19 and the bottom of connecting rod 15 to and the junction of the bottom of T shape connecting pipe 19 and the top of outlet duct 16 can set up some structures and settings of lubricated and gas tightness protection, and these structures and settings exist in relevant field, consequently are in the utility model discloses in no longer describe.

Specifically, the small diameter connecting section 151 may be configured to have external threads, and the connecting assembly 1611 is a threaded pipe having an inner diameter equal to the diameter of the small diameter connecting section 151 of the connecting rod 15 and having internal threads that mate with the external threads of the connecting section 151, which may be welded or otherwise fixedly attached within the top orifice of the outlet pipe 16.

In a preferred embodiment, the top of the horizontal section of outlet tube 16 is provided with a connection 1621 to the outlet tube connection area 172 on the bottom surface of the flush tray 17. For example, a snap-fit connection, or a bolt-and-nut connection, may be provided. Preferably, the outlet connection area 172 is upwardly concave, and the top of the horizontal section of the outlet 16 is fitted into the concave portion of the outlet connection area 172, so that on one hand, the outlet 16 is prevented from sliding relative to the wash bowl 17 during rotation, and on the other hand, the position of the outlet 16 is slightly raised to prevent the outlet from being worn by touching a hard substrate.

In a preferred embodiment, the exit apertures provided in the horizontal section 162 of the exit tube 16 include those directed vertically downward from the brushing disk 17 and those directed parallel to the brushing disk 17. The vertical air vents are more conducive to agitating the substrate, while the parallel air vents are conducive to washing the substrate away from the bristles 18 so that the sample does not adhere to the bristles 18 and can enter the collection tube 22 as far as possible.

The above description is only for the preferred embodiment of the present invention, and is not intended to limit the present invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included within the protection scope of the present invention.

Claims (9)

1. The utility model provides a benthos sampling device, includes ration portion (1) and collection portion (2), its characterized in that, set up bed mud agitating unit in ration portion (1), ration portion is including cubic main part (11), air pump (12) and trachea (13), penetrating around main part (11), collection portion (2) with the back intercommunication of main part (11), main part (11) two sides of main part (11) are provided with the baffle, and the bottom is for having the opening of known area, air pump (12) set up on main part (11), the one end of trachea (13) with air pump (12) intercommunication, the other end sets up the bottom of main part (11).

2. The benthic organism sampling device according to claim 1, wherein a support part is provided on the top of the main body (11), and the air pump (12) is provided on the support part.

3. Benthic organism sampling device according to claim 2, comprising a plurality of said air pipes (13), the majority of said air pipes (13) being arranged on baffles on the sides of the body (11), the bottom opening towards the vertical baffle.

4. The benthic organism sampling device according to claim 1, further comprising a motor (14), a connecting rod (15), an air outlet pipe (16), a scouring disk (17), bristles (18), and a T-shaped connecting pipe (19), the T-shaped connecting pipe (19) being communicated with the air pipe (13);

the motor (14) is arranged on the main body (11), the bristles (18) are arranged below the bottom surface of the flushing disc (17), the air outlet pipe (16) is connected with the flushing disc (17) and penetrates through the flushing disc (17), and an air outlet hole (1622) is formed in the part below the bottom surface of the flushing disc (17);

the motor (14) is fixedly connected with the top end of the air outlet pipe (16) through a connecting rod (15), the T-shaped connecting pipe (19) is clamped between the bottom end of the connecting rod (15) and the top end of the air outlet pipe (16), and the T-shaped connecting pipe (19) is communicated with the air outlet pipe (16).

5. The benthic organism sampling device according to claim 4, wherein the outlet pipe (16) is a hollow T-shaped pipe, the upper part is a vertical section (161), the lower part is a horizontal section (162), the horizontal section (162) is connected with the outlet pipe of the flushing disk (17), the vertical section (161) passes through the flushing disk (17), and the top end is above the flushing disk (17).

6. The benthic organism sampling device according to claim 4, wherein the bottom of the air outlet pipe (16) is positioned higher than the bottoms of the bristles (18).

7. The benthic organism sampling device according to claim 4, wherein the connecting rod (15) is connected at its top end to the motor (14) and at its bottom end to a small diameter connecting section (151), and the small diameter connecting section (151) passes through the T-shaped connecting pipe (19) and is connected at its end to the top end of the outlet pipe (16).

8. The benthic organism sampling apparatus according to claim 7, wherein a connecting member (1611) having a diameter smaller than the inner diameter of the outlet duct (16) is provided in the mouth of the top end of the outlet duct (16), and the end of the small diameter connecting section (151) of the connecting rod (15) is connected to the connecting member (1611).

9. The benthic organism sampling device according to claim 8, wherein the small diameter connection section (151) and the connection assembly (1611) are connected by a screw thread or a snap fit.

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