CN217786623U - Floating type water body sampling device for environment monitoring - Google Patents

Abstract

The utility model provides a floating water body sampling device for environmental monitoring, which relates to the technical field of water body sampling devices and comprises a positioning part and a sampling component, wherein the top of the positioning part is provided with a hydrographic component connected by an end bolt, the top end of the hydrographic component is provided with a hoisting buoyancy member, and the inner side of the buoyancy member is provided with the sampling component connected by a clamping way; the utility model discloses mainly utilize the block at the inboard sampling subassembly of buoyancy member, because the test tube section of thick bamboo of tube-shape contains in the sampling subassembly, and test tube section of thick bamboo inside contains two net covers and porous sieve that are parallel to each other respectively, can carry out the layering to the water sample of drawing like this in the test tube section of thick bamboo, so that when the user later stage carries out research and analysis, alleviate the burden of work, simultaneously because under mutually supporting of hole structure and net cover on the body, can make the product can not be because of the jam that the reason of impurity leads to, make equipment can use many times after the clearance, the rate of utilization has been promoted.

Description

Floating type water body sampling device for environment monitoring

Technical Field

The utility model relates to a water sampling device technical field especially relates to a float formula water sampling device for environmental monitoring.

Background

The water body collected by the water body sampling device is analyzed and determined to obtain basic data of water body detection and analysis, a water sample for analysis is representative, chemical composition and characteristics of the water body can be reflected, and a sampling method, a sampling position, sampling time, sampling times and the like are determined according to the characteristics of the water body and the analysis purpose.

Current water sampling device is in the use, and the rate of utilization is low, is difficult to carry out classification after the water intaking moreover, has the hidden danger scheduling problem of jam, consequently, the utility model provides a float formula water sampling device for environmental monitoring with the problem of solving existence among the prior art.

SUMMERY OF THE UTILITY MODEL

To the problem, the utility model provides a float formula water sampling device for environmental monitoring, this a float formula water sampling device for environmental monitoring mainly utilizes the block at the inboard sampling subassembly of buoyancy component, because the test tube section of thick bamboo of tube-shape contains among the sampling subassembly, and test tube section of thick bamboo inside contains two net covers and the porous sieve that are parallel to each other respectively, can carry out the layering to the water sample of drawing in the test tube section of thick bamboo like this, so that when the user later stage carries out research and analysis, alleviate the burden of work, simultaneously because under mutually supporting of hole structure and net cover on the body, can make the jam that the product can not lead to because of the reason of impurity, make equipment can use many times after the clearance, the rate of utilization has been promoted.

For realizing the purpose of the utility model, the utility model discloses a following technical scheme realizes: a floating water body sampling device for environment monitoring comprises a positioning part and a sampling assembly, wherein the top of the positioning part is provided with a hydrographic assembly connected by an end bolt, the top end of the hydrographic assembly is provided with a lifted buoyancy member, the inner side of the buoyancy member is provided with the sampling assembly connected by clamping, and the top side of the buoyancy member is provided with a display mechanism assembled by bolts;

the sampling subassembly includes backing ring, bolt hanging ring, examination barrel, net cover and porous sieve, the backing ring block is connected the interior limit side of buoyancy member, the top side of backing ring is provided with the bolt hanging ring of bolt assembly, the below of backing ring is provided with the examination barrel, the inboard of examination barrel is provided with the net cover and the porous sieve that parallel distribution each other.

The test tube is further improved in that the side of the top end of the test tube barrel is of a porous structure, the grid cover and the porous sieve are parallel to each other, the grid cover is located above the porous sieve, the grid cover is of a grid structure, and the porous sieve is of a sieve pore structure.

The improved structure is characterized in that the positioning part comprises an insertion cone, a counterweight discus, anti-sinking balls, an iron chain and a hanging ring, wherein the counterweight discus is arranged above the insertion cone of the cone, four sets of anti-sinking balls are annularly distributed on the side of the counterweight discus, and the top side of the counterweight discus is connected with the hanging ring through an iron chain ring sleeve.

The improved hydrographic subassembly includes that the rotation dish seat, first rotation frame, second rotate the frame, the third rotates frame, bearing strip and water wheels blade, the rotation dish seat sets up the top side of rings, the top of rotation dish seat is provided with first rotation frame, just the inboard bearing of first rotation frame is connected with the second and rotates the frame, the inboard bearing that the second rotated the frame is connected with the third and rotates the frame, just the inboard that the third rotated the frame is passed through the bearing strip and is connected with water wheels blade bearing.

The buoyancy member comprises a lifting rope, a buoy ring seat, a side rod and a buoyancy ball, the lifting rope is arranged on the top side of the first rotating frame, the buoy ring seat is arranged on the top side of the lifting rope, and the two sides of the buoy ring seat are connected with the buoyancy ball through the side rod.

The improved display mechanism comprises a bolt support, an upper rod, a solar photovoltaic plate, an inner transverse rod, a lamp holder and a signal lamp, wherein the bolt support is connected with the top side of the buoy ring seat through a bolt, the top end of the bolt support is supported by the solar photovoltaic plate through the upper rod, the inner transverse rod is arranged on the inner side of the bolt support, and the inner transverse rod is electrically connected with the signal lamp through the lamp holder.

The utility model has the advantages that:

the utility model discloses mainly utilize the block at the inboard sampling subassembly of buoyancy component, because the test tube section of thick bamboo of tube-shape contains in the sampling subassembly, and test tube section of thick bamboo inside contains two net covers and the porous sieve that are parallel to each other respectively, can carry out the layering to the water sample of drawing in the test tube section of thick bamboo like this, so that when the user later stage carries out research and analysis, alleviate the burden of work, simultaneously because under mutually supporting of hole structure and net cover on the body, can make the product can not use because of the jam that the reason of impurity leads to, make equipment use many times after the clearance, the rate of utilization has been promoted.

Drawings

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

fig. 2 is a schematic bottom perspective view of the present invention;

FIG. 3 is a schematic view of a three-dimensional structure of the hydrological assembly of the present invention;

fig. 4 is a schematic diagram of a three-dimensional structure of the sampling assembly of the present invention.

Wherein: 1. a positioning member; 101. inserting a cone; 102. a counterweight discus; 103. preventing the ball from sinking; 104. an iron chain; 105. a hoisting ring; 2. a hydrological component; 201. rotating the disc base; 202. a first rotating frame; 203. a second rotating frame; 204. a third rotating frame; 205. a bearing strip; 206. a water wheel blade; 3. a buoyant member; 301. a lifting rope; 302. a buoy ring seat; 303. a side lever; 304. a buoyant ball; 4. a sampling component; 401. a backing ring; 402. a bolt hanging ring; 403. testing the tube barrel; 404. a grid cover; 405. a porous screen; 5. a display mechanism; 501. a bolt bracket; 502. a rod is arranged; 503. a solar photovoltaic panel; 504. an inner horizontal bar; 505. a lamp socket; 506. provided is a signal lamp.

Detailed Description

In order to deepen the understanding of the present invention, the following embodiments will be combined to make the present invention do further details, and the present embodiment is only used for explaining the present invention, and does not constitute the limitation of the protection scope of the present invention.

According to the drawings of fig. 1-4, the embodiment provides a floating water body sampling device for environmental monitoring, which includes a positioning component 1 and a sampling component 4, wherein the top of the positioning component 1 is provided with a hydrographic component 2 connected by an end bolt, the top end of the hydrographic component 2 is provided with a suspended buoyancy member 3, the inner side of the buoyancy member 3 is provided with the sampling component 4 connected by a clamping, and the top side of the buoyancy member 3 is provided with a display mechanism 5 assembled by a bolt;

the sampling assembly 4 comprises a backing ring 401, a bolt hanging ring 402, a test tube cylinder 403, a grid cover 404 and a porous sieve 405, wherein the backing ring 401 is connected to the inner side of the buoyancy member 3 in a clamping mode, the bolt hanging ring 402 assembled through bolts is arranged on the top side of the backing ring 401, the test tube cylinder 403 is arranged below the backing ring 401, and the grid cover 404 and the porous sieve 405 which are distributed in parallel are arranged on the inner side of the test tube cylinder 403.

The top end side of the test tube barrel 403 is in a porous structure, the grid cover 404 and the porous sieve 405 are parallel to each other, the grid cover 404 is positioned above the porous sieve 405, the grid cover 404 is in a grid structure, and the porous sieve 405 is in a sieve pore structure.

In this embodiment, when the backing ring 401 with the bolt suspension ring 402 is engaged with the inner side of the buoy ring seat 302, the test tube barrel 403 below the backing ring 401 is fixed on the buoyancy member 3, because the top edge of the test tube barrel 403 has a porous structure, the water body in the water area can enter the test tube barrel 403, the grid cover 404 and the porous sieve 405 installed inside the test tube barrel 403 are parallel to each other, and the pores of the grid cover 404 are larger than those of the porous sieve 405, so that the water body in the water area borne by the test tube barrel 403 is divided into three layers, and after the user takes out the sampling assembly 4, the three layers of water bodies in different states can be taken out after the test tube barrel 403 is broken, so that the user can perform accurate and efficient research and observation.

The positioning component 1 comprises an insertion cone 101, a counterweight discus 102, anti-sinking balls 103, an iron chain 104 and a hanging ring 105, wherein the counterweight discus 102 is arranged above the tapered insertion cone 101, four groups of anti-sinking balls 103 are annularly distributed on the side of the counterweight discus 102, and the top side of the counterweight discus 102 is connected with the hanging ring 105 through the iron chain 104 in an annular manner.

In this embodiment, first, a place in a water area is selected, a plurality of sets of conical insertion cones 101 are installed below a counterweight discus 102, so that the counterweight discus 102 can be smoothly inserted under the riverbed of a water course, the anti-sinking balls 103 distributed annularly are arranged on the side of the counterweight discus 102, so that the equipment cannot be drawn out when being immersed in silt, and the hanging ring 105 is looped on the top side of the counterweight discus 102 by using the iron chain 104, so that the hanging ring 105 loops the rotating disc seat 201.

The hydrological assembly 2 comprises a rotating disc seat 201, a first rotating frame 202, a second rotating frame 203, a third rotating frame 204, a bearing strip 205 and a water turbine blade 206, wherein the rotating disc seat 201 is arranged on the top side of the hanging ring 105, the first rotating frame 202 is arranged at the top end of the rotating disc seat 201, the inner side of the first rotating frame 202 is in bearing connection with the second rotating frame 203, the inner side of the second rotating frame 203 is in bearing connection with the third rotating frame 204, and the inner side of the third rotating frame 204 is in bearing connection with the water turbine blade 206 through the bearing strip 205.

In this embodiment, since the rotating disc base 201 is connected to the first rotating frame 202 through a bearing, the first rotating frame 202 is connected to the second rotating frame 203 through a bearing, and the second rotating frame 203 is connected to the third rotating frame 204 through a bearing, under the driving of the water flow, the water turbine blades 206 outside the bearing strips 205 can be adaptively adjusted according to the direction and the strength of the water flow, so that the hydrological assembly 2 can achieve the effect of detecting the hydrological information according to the flow velocity and the flow direction of the water flow by the sensor on the self-carrying side.

The buoyancy member 3 includes a lifting rope 301, a pontoon ring seat 302, a side lever 303, and buoyancy balls 304, the lifting rope 301 is disposed on the top side of the first rotation frame 202, the pontoon ring seat 302 is disposed on the top side of the lifting rope 301, and the buoyancy balls 304 are connected to both sides of the pontoon ring seat 302 through the side lever 303.

In this embodiment, the buoy ring base 302 is connected to the top side of the first rotating frame 202 through the lifting rope 301, and the buoy ring base 302 is of an annular structure, so that the pad ring 401 can be clamped by the buoy ring base 302, and meanwhile, the buoyancy balls 304 mounted on two sides of the buoy ring base 302 through the side rods 303 are of a bag-shaped structure, so that the equipment can float on the water surface for a long time and cannot sink.

Display mechanism 5 includes bolt support 501, upper boom 502, solar photovoltaic board 503, interior horizontal stick 504, lamp stand 505 and signal lamp 506, and bolt support 501 bolted connection has solar photovoltaic board 503 on the top side of flotation pontoon ring seat 302, and bolt support 501's top has supported solar photovoltaic board 503 through upper boom 502, and bolt support 501's interior limit side is provided with interior horizontal stick 504, goes up through lamp stand 505 and signal lamp 506 electric connection on the horizontal stick 504.

In this embodiment, through the top side bolted connection at flotation pontoon ring seat 302 on bolted connection 501, make bolted connection 501 utilize upper boom 502 to support solar photovoltaic board 503, make the contrary electric ware that self carried on the cooperation of solar photovoltaic board 503 carry out the supply of power for display mechanism 5, after the power provides, make signal lamp 506 through lamp stand 505 electrical property grafting on the inboard interior horizontal rod 504 of bolted connection 501 provide the electric energy, let signal lamp 506 send light, in order to avoid the ship to be close to the security of lifting means, can indicate the concrete position of staff's equipment equally.

The working principle of the floating water body sampling device for environment monitoring is as follows: firstly, a place in a water area is selected, a plurality of groups of conical inserting cones 101 are arranged below a counterweight discus 102, so that the counterweight discus 102 can be smoothly inserted below the riverbed of a water channel, the annular distributed anti-sinking balls 103 are arranged at the side of the counterweight discus 102, equipment cannot be pulled out without being sunk into silt, the hoisting ring 105 is sleeved on the top side of the counterweight discus 102 by using a steel chain 104, so that the hoisting ring 105 is used for sleeving a rotating disc seat 201, because the rotating disc seat 201 is in bearing connection with a first rotating frame 202, the first rotating frame 202 is in bearing connection with a second rotating frame 203, the second rotating frame 203 is also in bearing connection with a third rotating frame 204, under the driving of water flow, the blades 206 outside a bearing strip 205 can be adaptively adjusted according to the direction and the strength of the water flow, the hydrographic component 2 can achieve the effect of detecting hydrographic information according to the flow velocity and the flow direction of water flow with a sensor on the side, the buoy ring seat 302 is connected with the top side of the first rotating frame 202 through a lifting rope 301, the buoy ring seat 302 can clamp the backing ring 401, the buoyancy balls 304 mounted on the side rods 303 are utilized on the two sides of the buoy ring seat 302, the buoyancy balls 304 are of a bag-shaped structure, so that equipment can float on the water surface for a long time and cannot sink, when the backing ring 401 mounted with the bolt lifting ring 402 is clamped on the inner side of the buoy ring seat 302, the test tube barrel 403 below the backing ring 401 is fixed on the buoyancy member 3, the water body in the water area can enter the test tube 403 due to the porous structure on the side of the top of the test tube 403, and the grid cover 404 and the porous sieve 405 mounted on the inner side of the test tube 403 are parallel to each other, and the holes of the grid cover 404 are also larger than the holes of the porous sieve 405, so that the water body in the water area borne by the test tube barrel 403 is divided into three layers, and after the user takes out the sampling assembly 4, the test tube barrel 403 can be broken open, and then the three layers of water bodies in different states are taken out, so that the user can conveniently carry out accurate and efficient research and observation.

The foregoing illustrates and describes the principles, general features, and advantages of the present invention. It should be understood by those skilled in the art that the present invention is not limited to the above embodiments, and the above embodiments and descriptions are only illustrative of the principles of the present invention, and that various changes and modifications may be made without departing from the spirit and scope of the present invention, and all such changes and modifications fall within the scope of the present invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (6)

1. The utility model provides a float formula water sampling device for environmental monitoring, includes locating component (1) and sampling component (4), its characterized in that: the top of the positioning component (1) is provided with a hydrographic assembly (2) connected with an end bolt, the top end of the hydrographic assembly (2) is provided with a hoisting buoyancy member (3), the inner side of the buoyancy member (3) is provided with a sampling assembly (4) connected in a clamping manner, and the top side of the buoyancy member (3) is provided with a display mechanism (5) assembled by bolts;

sampling subassembly (4) are including backing ring (401), bolt hanging ring (402), test tube section of thick bamboo (403), net cover (404) and porous sieve (405), backing ring (401) block is connected the inside flank side of buoyancy member (3), the top side of backing ring (401) is provided with bolt hanging ring (402) of bolt assembly, the below of backing ring (401) is provided with test tube section of thick bamboo (403), the inboard of test tube section of thick bamboo (403) is provided with grid cover (404) and porous sieve (405) that parallel distribution each other.

2. A floating water sampling device for environmental monitoring as claimed in claim 1 wherein: the top avris of test tube section of thick bamboo (403) is porous structure, net cover (404) and porous sieve (405) are parallel to each other, just net cover (404) is located the top of porous sieve (405), net cover (404) is latticed structure, porous sieve (405) are sieve mesh structure.

3. A floating water sampling device for environmental monitoring as claimed in claim 1 wherein: locating part (1) is including inserting awl (101), counter weight discus (102), preventing sinking ball (103), iron chain (104) and rings (105), the awl (101) top of inserting of awl (101) of awl is provided with counter weight discus (102), just the avris annular distribution of counter weight discus (102) has four groups to prevent sinking ball (103), the top side of counter weight discus (102) is connected with rings (105) through iron chain (104) ring cover.

4. A floating water sampling device for environmental monitoring as claimed in claim 3 wherein: hydrologic component (2) rotate frame (203), third including rotatory plate base (201), first rotation frame (202), second, rotate frame (204), bearing bar (205) and water wheel blade (206), rotatory plate base (201) set up the top side of rings (105), the top of rotatory plate base (201) is provided with first rotation frame (202), just the inboard bearing of first rotation frame (202) is connected with second rotation frame (203), the inboard bearing that second rotated frame (203) is connected with third rotation frame (204), just the inboard of third rotation frame (204) is passed through bearing bar (205) and is connected with water wheel blade (206) bearing.

5. A floating water sampling device for environmental monitoring as claimed in claim 4 wherein: buoyancy member (3) include lifting rope (301), flotation pontoon ring seat (302), side lever (303) and buoyancy ball (304), lifting rope (301) set up the top side of first rotation frame (202), the top side of lifting rope (301) is provided with flotation pontoon ring seat (302), just the both sides of flotation pontoon ring seat (302) are connected with buoyancy ball (304) through side lever (303).

6. A floating water sampling device for environmental monitoring as claimed in claim 5 wherein: display mechanism (5) include bolt support (501), upper boom (502), solar photovoltaic board (503), interior horizontal stick (504), lamp stand (505) and signal lamp (506), bolt support (501) bolted connection be in the top side of flotation pontoon ring seat (302), the top of bolt support (501) has supported solar photovoltaic board (503) through upper boom (502), the interior limit side of bolt support (501) is provided with interior horizontal stick (504), interior horizontal stick (504) go up through lamp stand (505) and signal lamp (506) electric connection.

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