CN212904030U - Novel floated water quality monitoring sample device - Google Patents

Abstract

The utility model provides a novel floated water quality monitoring sampling device, solved when carrying out the water sampling, mostly borrow the ship and go to the collection, it is neither convenient safe again, and can only drop into a sample bottle into the aquatic at every turn and pour into the sample, such sampling method can not take a sample to the waters of the different degree of depth, if put the degree of depth that will gather the water sample with the sample bottle, at the in-process of up-lifting, the sample also can change, so cause the unsafe problem of sample of collection. The technical scheme of the utility model is realized through following technical scheme: the utility model provides a novel floated water quality monitoring sampling device, its constitution includes: the device comprises an external frame, a driving device, a telescopic support and a fixing device, wherein a cross beam in the external frame is connected with an iron plate in the driving device through a bolt, the iron plate in the driving device is connected with an upper linear guide rail in the telescopic support through a bolt, and a lower linear guide rail in the telescopic support is connected with a water pump plate in the fixing device through a bolt.

Description

Novel floated water quality monitoring sample device

Technical Field

The utility model relates to a technical field of aeration tank sewage treatment especially relates to a novel floated water quality monitoring sampling device.

Background

Water is a source of life, water quality problems directly affect human living environment, and in environment monitoring work, water quality sampling is an important link, so how to enable a collected water sample to truly and accurately reflect water quality conditions is a problem which must be solved firstly in monitoring and analyzing work.

SUMMERY OF THE UTILITY MODEL

The utility model discloses to above problem, the utility model provides a novel floated water quality monitoring sampling device, solved when carrying out water sampling, mostly borrow the ship to go to gather, it is neither convenient but unsafe, and can only drop into a sample bottle into the aquatic at every turn and pour into the sample, such sampling method can not take a sample to the waters of the different degree of depth, if will take a sample bottle and put the degree of depth that will gather the water sample, at the in-process of up-lifting, the sample also can change, so cause the unsafe problem of sample of gathering.

The technical scheme of the utility model is realized through following technical scheme:

the utility model provides a novel floated water quality monitoring sampling device, its constitution includes: the device comprises an outer frame 1, a driving device 2, a telescopic bracket 3 and a fixing device 4, wherein a cross beam 104 in the outer frame 1 is connected with an iron plate 201 in the driving device 2 through a bolt, the iron plate 201 in the driving device 2 is connected with an upper linear guide rail 304 in the telescopic bracket 3 through a bolt, and a lower linear guide rail 308 in the telescopic bracket 3 is connected with a water pump plate 403 in the fixing device 4 through a bolt. When needs carry out this waters sample, meet the waters that will detect with equipment through the ship can, then hoist engine 202 through among drive arrangement 2 transfers telescopic bracket 3 wholly, the degree of depth that needs detected is different, accessible hoist engine 202 controlgear's descending depth, when reaching the depth of water position that will detect, carry out the microorganism that detects aquatic through sensor 401, the organic matter, heavy metal, multiple parameters such as disinfectant, and sample through water pump 404, the back is accomplished in the sample, shrink telescopic bracket 3 through hoist engine 202.

The external frame 1 is composed of a buoyancy ball 101, a buoyancy ball connecting plate 102, a vertical beam 103, a cross beam 104 and universal wheels 105, wherein the buoyancy ball 101 is connected with the buoyancy ball connecting plate 102 through bolts, the buoyancy ball connecting plate 102 is connected with the cross beam 104 through bolts, the vertical beam 103 is connected with the cross beam 104 through bolts, the universal wheels 105 are connected with the vertical beam 103 through bolts, and the buoyancy ball 101 is used for floating the whole equipment on the water surface.

The driving device 2 comprises an iron plate 201, a winch 202 and a hanging ring 203, wherein the iron plate 201 is connected with the winch 202 through bolts, the iron plate 201 is connected with the hanging ring 203 through bolts, a steel wire rope on the winch 202 bypasses a fixed pulley 405 and then is connected with the hanging ring 203 through clamping, and when equipment is used for sampling, the steel wire rope is placed through the winch 202, the equipment is added with the self gravity, and the equipment sinks to a water area to be detected for sampling.

The telescopic bracket 3 comprises a support shaft 301, telescopic plates 302, an upper slide block 303, an upper linear guide rail 304, a large shaft 305, a lower slide block 306, a lower linear guide rail 307 and a big lug seat 308, wherein the support shaft 301 and the telescopic plates 302 are matched through coaxiality and connected through bolts, the middle parts of the two telescopic plates 302 are connected through hinged hole bolts and can rotate around the hinged hole bolts, the upper slide block 303 and the big lug seat 308 are connected through the support shaft 301, the upper slide block 303 is in clearance fit with the upper linear guide rail 304, the upper slide block 303 can freely slide along the upper linear guide rail 304, the large shaft 305 is matched with the telescopic plates 302 through coaxiality and connected through bolts, the lower slide block 306 is connected with the telescopic plates 302 through the support shaft 301, the lower slide block 306 is in clearance fit with the lower linear guide rail 307, and the lower slide block 306 can freely slide along the lower linear guide rail 307.

The fixing device 4 is composed of a sensor 401, a sensor support 402, a water pump plate 403, a water pump 404 and a fixed pulley 405, wherein the sensor 401 is connected with the sensor support 402 through a bolt, the sensor support 402 is connected with the water pump plate 403 through a bolt, the water pump plate 403 is connected with the water pump 404 through a bolt, and the fixed pulley 405 is connected with the water pump plate 403 through a bolt.

The utility model has the advantages of during the sample, the degree of depth of extraction water sample can freely be adjusted, its simple structure, convenient operation.

Drawings

FIG. 1 is a schematic structural view of a novel suspension type water quality monitoring and sampling device;

fig. 2 is a schematic structural view of the outer frame 1 of fig. 1;

FIG. 3 is a schematic view of the structure of the driving device 2 in FIG. 1;

fig. 4 is a schematic structural view of the telescopic bracket 3 in fig. 1;

FIG. 5 is a schematic view of the structure of the fixing device 4 in FIG. 1;

Detailed Description

1. Referring to fig. 1, 2, 3, 4 and 5, a novel suspension type water quality monitoring and sampling device according to the present embodiment includes: the device comprises an outer frame 1, a driving device 2, a telescopic bracket 3 and a fixing device 4, wherein a cross beam 104 in the outer frame 1 is connected with an iron plate 201 in the driving device 2 through a bolt, the iron plate 201 in the driving device 2 is connected with an upper linear guide rail 304 in the telescopic bracket 3 through a bolt, and a lower linear guide rail 308 in the telescopic bracket 3 is connected with a water pump plate 403 in the fixing device 4 through a bolt.

2. Referring to fig. 2, the external frame 1 is composed of a buoyancy ball 101, a buoyancy ball connecting plate 102, a vertical beam 103, a cross beam 104 and a universal wheel 105, wherein the buoyancy ball 101 is connected with the buoyancy ball connecting plate 102 through a bolt, the buoyancy ball connecting plate 102 is connected with the cross beam 104 through a bolt, the vertical beam 103 is connected with the cross beam 104 through a bolt, the universal wheel 105 is connected with the vertical beam 103 through a bolt, and the buoyancy ball 101 is used for floating the whole equipment on the water surface.

3. Referring to fig. 3, the driving device 2 is composed of an iron plate 201, a winch 202 and a hanging ring 203, wherein the iron plate 201 is connected with the winch 202 through a bolt, the iron plate 201 is connected with the hanging ring 203 through a bolt, a steel wire rope on the winch 202 bypasses a fixed pulley 405 and then is connected with the hanging ring 203 through clamping, and when the device is used for sampling, the steel wire rope is lowered through the winch 202, the self gravity of the device is added, and the device sinks to a water area to be detected for sampling.

4. Referring to fig. 4, the telescopic bracket 3 is composed of a support shaft 301, telescopic plates 302, an upper slide block 303, an upper linear guide rail 304, a large shaft 305, a lower slide block 306, a lower linear guide rail 307 and a big lug seat 308, wherein the support shaft 301 and the telescopic plates 302 are coaxially matched and are connected by bolts, the middle parts of the two telescopic plates 302 are connected by a hinged hole bolt and can rotate around the hinged hole bolt, the upper slide block 303 and the big lug seat 308 are connected by the support shaft 301, the upper slide block 303 is in clearance fit with the upper linear guide rail 304, the upper slide block 303 can freely slide along the upper linear guide rail 304, the large shaft 305 and the telescopic plates 302 are coaxially matched and are connected by bolts, the lower slide block 306 and the telescopic plates 302 are connected by the support shaft 301, the lower slide block 306 is in clearance fit with the lower linear guide rail 307, and the lower slide block 306 can freely slide along the lower linear.

5. Referring to fig. 5, the fixing device 4 is composed of a sensor 401, a sensor bracket 402, a water pump plate 403, a water pump 404 and a fixed pulley 405, wherein the sensor 401 is connected with the sensor bracket 402 by bolts, the sensor bracket 402 is connected with the water pump plate 403 by bolts, the water pump plate 403 is connected with the water pump 404 by bolts, and the fixed pulley 405 is connected with the water pump plate 403 by bolts.

It is emphasized that the examples set forth in this patent are intended to be illustrative, and not limiting, and thus, this patent includes embodiments that are not limited to those described in the detailed description, as well as other embodiments that can be derived from the teachings of the patent by those skilled in the art, and are intended to be within the scope of the patent.

Claims (1)

1. A novel suspended water quality monitoring and sampling device is characterized by comprising an external frame (1), a driving device (2), a telescopic bracket (3) and a fixing device (4), wherein a cross beam (104) in the external frame (1) is connected with an iron plate (201) in the driving device (2) through bolts, the iron plate (201) in the driving device (2) is connected with an upper linear guide rail (304) in the telescopic bracket (3) through bolts, and a lower linear guide rail (307) in the telescopic bracket (3) is connected with a water pump plate (403) in the fixing device (4) through bolts; the external frame (1) is composed of a buoyancy ball (101), a buoyancy ball connecting plate (102), a vertical beam (103), a cross beam (104) and universal wheels (105), wherein the buoyancy ball (101) is connected with the buoyancy ball connecting plate (102) through bolts, the buoyancy ball connecting plate (102) is connected with the cross beam (104) through bolts, the vertical beam (103) is connected with the cross beam (104) through bolts, the universal wheels (105) are connected with the vertical beam (103) through bolts, and the buoyancy ball (101) is used for floating the whole equipment on the water surface; the driving device (2) consists of an iron plate (201), a winch (202) and a lifting ring (203), wherein the iron plate (201) is connected with the winch (202) through a bolt, the iron plate (201) is connected with the lifting ring (203) through a bolt, a steel wire rope on the winch (202) bypasses a fixed pulley (405) and then is connected with the lifting ring (203) through clamping, and when the device is used for sampling, the steel wire rope is lowered through the winch (202) and the self gravity of the device, and then the device is sunk to a water area to be detected for sampling; the telescopic support (3) consists of a support shaft (301), telescopic plates (302), an upper sliding block (303), an upper linear guide rail (304), a large shaft (305), a lower sliding block (306), a lower linear guide rail (307) and a big lug seat (308), wherein the support shaft (301) is matched with the telescopic plates (302) through coaxiality and connected through bolts, the middle parts of the two telescopic plates (302) are connected through a hinged hole bolt and can rotate around the hinged hole bolt, the upper sliding block (303) is connected with the big lug seat (308) through the support shaft (301), the upper sliding block (303) is in clearance fit with the upper linear guide rail (304), the upper sliding block (303) can freely slide along the upper linear guide rail (304), the large shaft (305) is matched with the telescopic plates (302) through coaxiality and connected through bolts, the lower sliding block (306) is connected with the telescopic plates (302) through the support shaft (301), and the lower sliding block (306) is in clearance fit with the lower linear guide rail (307), the lower sliding block (306) can freely slide along the lower linear guide rail (307); the fixing device (4) is composed of a sensor (401), a sensor support (402), a water pump plate (403), a water pump (404) and a fixed pulley (405), wherein the sensor (401) is connected with the sensor support (402) through a bolt, the sensor support (402) is connected with the water pump plate (403) through a bolt, the water pump plate (403) is connected with the water pump (404) through a bolt, and the fixed pulley (405) is connected with the water pump plate (403) through a bolt.

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