CN111175080A

CN111175080A - Wetland quality of water chemical element measures supplementary collection device

Info

Publication number: CN111175080A
Application number: CN202010101120.6A
Authority: CN
Inventors: 不公告发明人
Original assignee: Wenzhou Yanggefan Electronic Technology Co Ltd
Current assignee: ANHUI AOCHUANG ENVIRONMENT DETECTION Co.,Ltd.
Priority date: 2020-02-19
Filing date: 2020-02-19
Publication date: 2020-05-19
Anticipated expiration: 2040-02-19
Also published as: CN111175080B

Abstract

The invention discloses a wetland water quality chemical element measurement auxiliary collecting device, which comprises a ship body, wherein a collecting mechanism for collecting water samples is arranged in the ship body, the collecting mechanism comprises a lifting cavity which is positioned in the ship body and has an upward opening, a driving cavity with a leftward opening is arranged in the wall at the right end of the lifting cavity, a liftable piston column is arranged in the lifting cavity, a piston cavity penetrating through the upper end surface and the lower end surface of the ship body is arranged in the piston column, a through hole for communicating the piston cavity with the lifting cavity is arranged on the wall at the lower end of the piston cavity, and a lifting plate is connected in the piston cavity in a sliding manner. The result can be compared more intuitively.

Description

Wetland quality of water chemical element measures supplementary collection device

Technical Field

The invention relates to the field of chemical equipment, in particular to an auxiliary collecting device for measuring chemical elements in wetland water quality.

Background

The wetland refers to an area where the surface is over-wet or water is accumulated frequently to grow wetland organisms, and has multiple functions of protecting biodiversity, regulating runoff, improving water quality, regulating microclimate, providing food and industrial raw materials and providing tourism resources;

therefore, the protection of the wetland is particularly important, water resources are indispensable and very important components of the wetland, enterprises close to the wetland may discharge wastewater which does not meet the requirements and enter the wetland to influence the water quality of the wetland, and the multi-point water quality chemical element detection of the wetland is particularly important.

Disclosure of Invention

The invention aims to solve the technical problem of providing an auxiliary collecting device for measuring chemical elements in the water quality of a wetland, which solves the problems of low efficiency and the like, thereby improving the efficiency.

The invention is realized by the following technical scheme.

The invention relates to a wetland water quality chemical element measurement auxiliary collecting device, which comprises a ship body, wherein a collecting mechanism for collecting water samples is arranged in the ship body, the collecting mechanism comprises a lifting cavity which is positioned in the ship body and has an upward opening, a driving cavity with a leftward opening is arranged in the right end wall of the lifting cavity, a liftable piston column is arranged in the lifting cavity, a piston cavity penetrating through the upper end surface and the lower end surface of the ship body is arranged in the piston column, a through hole for communicating the piston cavity with the lifting cavity is arranged on the lower end wall of the piston cavity, a lifting plate is connected in the piston cavity in a sliding manner, a lifting rod with an upper end penetrating through the upper end wall of the lifting cavity and positioned outside is fixed at the upper end of the lifting plate, a first electric guide rail is fixed on the right end wall of the driving cavity, a supporting plate which can be driven by the first electric guide rail, the left end of the supporting spring is fixedly connected with the piston column, the upper side of the supporting plate is provided with a lifting column, the upper end of the lifting column is fixedly provided with a connecting plate, the left end of the connecting plate is fixedly connected with the upper end of the lifting rod, the upper end of the lifting column is provided with a fixed block, the fixed block can be driven to lift, the lower end of the lifting column is fixedly provided with a supporting block, the supporting block is internally provided with a sliding groove with an upward opening, the sliding groove is internally and slidably connected with a sliding block, the upper end of the sliding block is fixedly provided with a connecting spring, the upper end of the connecting spring is fixedly connected with the fixed block, the lower end of the sliding block is fixedly provided with an electromagnetic plate, the left end of the sliding plate is fixedly connected with the sliding groove, the left side of the lower end of the lifting column is provided with an electromagnetic plate attracted with the lifting column, and the right end of the electromagnetic plate is fixedly provided with a sliding spring, the, the water sample lifting device is characterized in that a sealing mechanism is arranged in the lower end wall of the driving cavity and communicated with the outside, and a detection mechanism used for detecting and collecting water samples is further arranged in the left end wall of the lifting cavity.

Furthermore, the closing mechanism comprises a moving cavity which is positioned in the lower end wall of the driving cavity and is penetrated through by the lower end wall of the lifting cavity, a magnet plate is fixed on the right end wall of the moving cavity, a fixed rod is fixedly connected between the upper end wall and the lower end wall of the moving cavity, a magnet block which is repelled by the magnet plate is also connected in the moving cavity in a sliding manner, the magnet block is fixedly connected with the fixed rod through a moving spring, a telescopic clapboard is fixed on the lower end section of the supporting plate, the lower end of the telescopic clapboard penetrates through the lower end wall of the driving cavity and is positioned in the moving cavity, a spring cavity with an upward opening and communicated with the lifting cavity is arranged in the magnet block, a piston block with the upper end contacted with the lower end of the piston column and a telescopic spring supporting the piston block are arranged in the spring cavity, and an outflow pipeline which penetrates through the piston block and the, and a communicating pipeline is further arranged in the piston block, the upper end wall and the left end wall of the piston block are communicated with the lifting cavity, and an electromagnetic valve is arranged in the communicating pipeline.

Further, the detection mechanism comprises a lifting cavity positioned between the left end wall of the lifting cavity, a second electric guide rail is fixed on the left end wall of the lifting cavity, a lifting groove with a left opening is arranged in the right end wall of the lifting cavity, a driving plate with a right end positioned in the lifting groove and driven by the second electric guide rail to lift is arranged in the lifting cavity, an electromagnetic rod is arranged on the upper side of the driving plate, an upper end of the electromagnetic rod is fixed with a lifting spring fixedly connected with the upper end wall of the lifting cavity, an electromagnetic block positioned on the upper side of the driving plate is arranged in the lifting groove, an upper end of the electromagnetic block is fixed with a lifting spring fixedly connected with the upper end wall of the lifting groove, four lower ends of the electromagnetic rod penetrate through the driving plate and are positioned on a detector of the lower side, a driving plate rack is fixed between the left end wall and the right end wall of the lifting cavity, and four, be equipped with the intercommunication in the lift chamber right-hand member wall the lift chamber with the slip pipeline in lifting chamber, sliding connection has the left end to be located in the slip pipeline the removal pipeline in the lift intracavity, be equipped with the opening shifting chute to the left in the slip pipeline upper end wall, sliding connection has the left end to be located in the shifting chute the lift intracavity and with shifting chute left end fixed connection's L pole, still be equipped with the connection in the shifting chute right-hand member wall with the compression spring of L pole left end wall, L pole right-hand member is fixed with the right-hand member and runs through the shifting chute right end wall with lifting groove lower extreme wall and with electromagnetic block fixed connection's rope.

Furthermore, the magnetic force between the electromagnetic plate and the lifting column is greater than the sum of the elastic force of the sliding spring and the elastic force of the connecting spring, and the sliding block is provided with an inclined surface.

The invention has the beneficial effects that: the device simple structure, the simple operation through mechanical transmission, and the automatic wetland water resource that accomplishes multiple spot and different degree of depth is collected, and the chemical element in the final completion water detects, very big improvement water quality testing's efficiency and make the detection data diversified, and the detection data of the water of final multiple collection owing to reacing simultaneously, can comparatively audio-visual contrast out the result.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

FIG. 1 is a schematic structural diagram of an embodiment of the present invention;

FIG. 2 is an enlarged schematic view of the structure at A in FIG. 1 according to an embodiment of the present invention;

FIG. 3 is an enlarged view of the structure at B in FIG. 1 according to an embodiment of the present invention.

Detailed Description

The invention will now be described in detail with reference to fig. 1-3, wherein for ease of description the orientations described hereinafter are now defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

With reference to fig. 1-3, a wetland quality of water chemical element measures supplementary collection device, including hull 10, be equipped with the collection mechanism 61 that is used for collecting the water sample in the hull 10, collect mechanism 61 including being located in the hull 10 and ascending lifting chamber 16 of opening, be equipped with the drive chamber 24 of opening left in the lifting chamber 16 right-hand member wall, be equipped with liftable piston post 22 in the lifting chamber 16, be equipped with in the piston post 22 and run through the piston chamber 21 of the terminal surface about the hull 10, the lower extreme wall of piston chamber 21 is equipped with the intercommunication piston chamber 21 with the perforating hole 63 in lifting chamber 16, sliding connection has lifting plate 50 in piston chamber 21, lifting plate 50 upper end is fixed with the upper end and runs through lifting chamber 16 upper end wall and be located outside lifter 17, drive chamber 24 right-hand member wall is fixed with first electronic guide rail 25, be equipped with in the drive chamber 24 can be driven by first electronic guide rail 25 the backup pad 59 and the support that goes up and down The left end of the supporting spring 26 of the supporting plate 59 is fixedly connected with the piston column 22, the upper side of the supporting plate 59 is provided with a lifting column 20, the upper end of which penetrates through the upper end wall of the driving cavity 24 and is positioned outside, the upper end of the lifting column 20 is fixedly provided with a connecting plate 19, the left end of which is fixedly connected with the upper end of the lifting rod 17, the first electric guide rail 25 is also provided with a fixed block 56 which can be driven to lift, the lower end of the lifting column 20 is fixedly provided with a supporting block 58, the supporting block 58 is internally provided with a sliding groove 53 with an upward opening, the sliding groove 53 is internally and slidably connected with a sliding block 55, the upper end of which is in contact with the fixed block 56, the upper end of the supporting block 58 is fixedly provided with a connecting spring 57, the upper end of which is fixedly connected with the fixed block 56, the lower end of the sliding block 55 is fixedly provided with an electromagnetic plate 51, the left end of which is fixedly connected, electromagnetic plate 51 right-hand member is fixed with the right-hand member and runs through lifting column 20 with sliding tray 53 left end wall and with sliding block 55 fixed connection's sliding spring 54, be equipped with in the lower endwall of drive chamber 24 and seal lifting chamber 16 lower endwall and the closing mechanism 62 of outside intercommunication, still be equipped with the detection mechanism 60 that is used for detecting the collection water sample in the lifting chamber 16 left end wall.

Beneficially, the closing mechanism 62 includes a moving cavity 28 located in the lower end wall of the driving cavity 24 and penetrated by the lower end wall of the lifting cavity 16, a magnet plate 27 is fixed to the right end wall of the moving cavity 28, a fixing rod 29 is fixedly connected between the upper end wall and the lower end wall of the moving cavity 28, a magnet block 31 repelled by the magnet plate 27 is further slidably connected in the moving cavity 28, the magnet block 31 is fixedly connected with the fixing rod 29 through a moving spring 30, a telescopic partition plate 23 is fixed to the lower end section of the supporting plate 59, penetrates through the lower end wall of the driving cavity 24 and is located in the moving cavity 28, a spring cavity 33 with an upward opening and communicated with the lifting cavity 16 is arranged in the magnet block 31, a piston block 41 with an upper end contacting with the lower end of the piston column 22 and a telescopic spring 34 supporting the piston block 41 are arranged in the spring cavity 33, and a piston block 41 is arranged in the piston block 41, and penetrates through the lower end wall of the piston block 41 and and the outflow pipeline 40, a communication pipeline 43 which is provided with an upper end wall and a left end wall and is communicated with the lifting cavity 16 is further arranged in the piston block 41, and an electromagnetic valve 42 is arranged in the communication pipeline 43.

Beneficially, the detecting mechanism 60 includes a lifting chamber 11 located at the left end wall of the lifting chamber 16, a second electric guide rail 38 is fixed at the left end wall of the lifting chamber 11, a lifting groove 36 with a leftward opening is arranged in the right end wall of the lifting chamber 11, a driving plate 39 is arranged in the lifting chamber 11, the right end of the driving plate is located in the lifting groove 36 and can be driven by the second electric guide rail 38 to lift, an electromagnetic rod 13 is arranged at the upper side of the driving plate 39, a lifting spring 12 is fixed at the upper end of the electromagnetic rod 13 and is fixedly connected with the upper end wall of the lifting chamber 11, an electromagnetic block 15 located at the upper side of the driving plate 39 is arranged in the lifting groove 36, a lifting spring 14 is fixed at the upper end of the electromagnetic block 15 and is fixedly connected with the upper end wall of the lifting groove 36, four detectors 37 are fixed at the lower ends of the electromagnetic rod 13 and penetrate through the driving, be fixed with test-tube rack 32 between the end wall about lift chamber 11, four test tubes 35 have been placed on the test-tube rack 32, be equipped with the intercommunication in the 11 right-hand members wall in lift chamber 11 with the slip pipeline 44 in lifting chamber 16, sliding connection has the left end to be located in the slip pipeline 44 the removal pipeline 45 in the lift chamber 11, be equipped with opening shift chute 49 to the left in the slip pipeline 44 upper end wall, sliding connection has the left end to be located in the shift chute 49 lift chamber 11 and with the L pole 46 of 45 left end fixed connection of removal pipeline, still be equipped with the connection in the shift chute 49 right-hand members wall with the compression spring 47 of L pole 46 left end wall, L pole 46 right-hand member is fixed with the right end and runs through shift chute 49 right-hand members wall with 36 lower end wall of lifting groove and with electromagnetism piece 15 fixed connection's rope 48.

Advantageously, the magnetic force between the electromagnetic plate 51 and the lifting column 20 is greater than the sum of the elastic forces of the sliding spring 54 and the connecting spring 57, and the sliding block 55 is provided with a slope.

In the initial state, the moving spring 30, the slide spring 54, and the connecting spring 57 are in a stretched state, and the compression spring 47 is in a compressed state.

When the ship body 10 runs to a place for collecting samples, the ship body 10 stops advancing, the first electric guide rail 25 works to drive the supporting plate 59 to descend, so that the piston column 22 and the telescopic partition plate 23 are driven to descend, the piston column 22 descends to drive the piston block 41 to descend and compress the telescopic spring 34, the telescopic partition plate 23 descends to enable the lower end of the telescopic partition plate 23 to be located in the moving cavity 28, and when the piston block 41 is completely located in the spring cavity 33 and the telescopic partition plate 23 cuts off the connection between the magnet block 31 and the magnet plate 27, the moving spring 30 resets to drive the magnet block 31 to move leftwards, so that the lower end wall of the lifting cavity 16 is communicated with the outside;

at this time, the first electric guide rail 25 continues to drive the supporting plate 59 to descend, the telescopic partition plate 23 is compressed, the piston column 22 continues to descend, so that the first electric guide rail 25 stops moving when the lower end of the piston column 22 descends to the depth of collecting samples, at this time, the electromagnetic plate 51 stops working, so that the sliding spring 54 is reset to drive the sliding block 55 to move leftwards, so that the electromagnetic plate 51 and the connecting rod 52 move leftwards, and when the sliding block 55 leaves the lower side of the fixed block 56, the connecting spring 57 is reset to drive the supporting block 58 and the lifting column 20 to ascend, so that the lifting rod 17 and the connecting plate 19 ascend, so that the lifting plate 50 ascends, and water samples at the depth are extracted;

then the first electric guide 25 operates to drive the fixed block 56 and the supporting plate 59 to ascend, thereby driving the piston column 22 to ascend and the telescopic partition 23 to gradually return, when the first electric guide 25 operates to drive the piston column 22 to return, the telescopic partition 23 returns and no longer separates the magnet plate 27 and the magnet block 31, thereby enabling the magnet block 31 and the magnet plate 27 to repel each other, thereby enabling the magnet plate 27 to move leftward and enabling the moving spring 30 to be stretched, when the magnet block 31 returns, the piston block 41 ascends under the action of the telescopic spring 34, thereby enabling the water on the upper side of the piston block 41 to be pressed out of the lifting cavity 16 through the outflow pipe 40, when the water is pressed out, the communication pipe 43 communicates with the sliding pipe 44, then the electromagnetic valve 42 operates to enable the communication pipe 43 to communicate, at the moment, the electromagnetic plate 51 operates to attract the lifting column 20, thereby enabling the connecting rod 52 to move rightward, thereby enabling the sliding block 55 to move rightward and stretching the sliding spring 54, thereby lowering the supporting block 58 and stretching the connection spring 57, thereby lowering the lifting column 20 and the connection plate 19, and lowering the lifting lever 17 and the lifting plate 50, thereby introducing the collected water into the moving duct 45 through the through hole 63, the communication duct 43, and the sliding duct 44;

when water is collected, the electromagnetic block 15 works to attract the driving plate 39, so that the second electric guide rail 38 works to drive the driving plate 39 to descend, the electromagnetic block 15 descends, the lifting spring 14 is stretched, the rope 48 is loosened, the compression spring 47 is reset to drive the L rod 46 to move leftwards, the moving pipe 45 moves leftwards, and a sample can flow into the test tube 35 to be collected;

when detection is needed, the electromagnetic rod 13 is attracted to the driving plate 39 in operation, and at the moment, the second electric guide rail 38 is operated to drive the driving plate 39 to descend, the detector 37 and the electromagnetic rod 13 also descend and stretch the lifting spring 12, so that the lower end of the detector 37 enters the test tube 35 to detect a water sample.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims

1. The utility model provides a wetland quality of water chemical element measures supplementary collection device, includes the hull, its characterized in that: the water sampler is characterized in that a collecting mechanism for collecting water samples is arranged in the ship body, the collecting mechanism comprises a lifting cavity which is positioned in the ship body and has an upward opening, a driving cavity with a leftward opening is arranged in the right end wall of the lifting cavity, a liftable piston post is arranged in the lifting cavity, a piston cavity which penetrates through the upper end surface and the lower end surface of the ship body is arranged in the piston post, a through hole which communicates the piston cavity with the lifting cavity is formed in the lower end wall of the piston cavity, a lifting plate is connected in the piston cavity in a sliding manner, a lifting rod with an upper end penetrating through the upper end wall of the lifting cavity and positioned outside is fixed at the upper end of the lifting plate, a first electric guide rail is fixed on the right end wall of the driving cavity, a supporting plate which can be driven by the first electric guide rail to lift and a supporting spring which supports the supporting plate are arranged in the driving cavity, the left end of the supporting spring is fixedly connected with, a connecting plate fixedly connected with the left end of the lifting column and the upper end of the lifting rod is fixed at the upper end of the lifting column, a fixed block capable of being driven to lift is further arranged on the first electric guide rail, a supporting block is fixed at the lower end of the lifting column, a sliding groove with an upward opening is arranged in the supporting block, a sliding block with the upper end contacted with the fixed block is connected in the sliding groove in a sliding mode, a connecting spring with the upper end fixedly connected with the fixed block is fixed at the upper end of the supporting block, an electromagnetic plate with the left end fixedly connected with the sliding groove is fixed at the lower end of the sliding block, an electromagnetic plate attracted with the lifting column is arranged on the left side of the lower end of the lifting column, a sliding spring with the right end penetrating through the lifting column and the left end wall of the sliding groove and fixedly connected with the sliding block is fixed at the right end of the electromagnetic plate, and a sealing mechanism, and a detection mechanism for detecting and collecting water samples is further arranged in the left end wall of the lifting cavity.

2. The wetland water quality chemical element measurement auxiliary collection device of claim 1, which is characterized in that: the sealing mechanism comprises a moving cavity which is positioned in the lower end wall of the driving cavity and is penetrated through by the lower end wall of the lifting cavity, a magnet plate is fixed on the right end wall of the moving cavity, a fixed rod is fixedly connected between the upper end wall and the lower end wall of the moving cavity, a magnet block which is repelled by the magnet plate is also connected in the moving cavity in a sliding manner, the magnet block is fixedly connected with the fixed rod through a moving spring, a telescopic clapboard is fixed on the lower end section of the supporting plate, the lower end of the telescopic clapboard penetrates through the lower end wall of the driving cavity and is positioned in the moving cavity, a spring cavity with an upward opening and communicated with the lifting cavity is arranged in the magnet block, a piston block with the upper end contacted with the lower end of the piston column and a telescopic spring supporting the piston block are arranged in the spring cavity, and an outflow pipeline which penetrates through the piston block, and a communicating pipeline is further arranged in the piston block, the upper end wall and the left end wall of the piston block are communicated with the lifting cavity, and an electromagnetic valve is arranged in the communicating pipeline.

3. The wetland water quality chemical element measurement auxiliary collection device of claim 2, which is characterized in that: the detection mechanism comprises a lifting cavity positioned between the left end wall of the lifting cavity, a second electric guide rail is fixed on the left end wall of the lifting cavity, a lifting groove with a left opening is arranged in the right end wall of the lifting cavity, a driving plate with a right end positioned in the lifting groove and driven to lift by the second electric guide rail is arranged in the lifting cavity, an electromagnetic rod is arranged on the upper side of the driving plate, a lifting spring with an upper end fixedly connected with the upper end wall of the lifting cavity is fixed on the upper end of the electromagnetic rod, an electromagnetic block positioned on the upper side of the driving plate is arranged in the lifting groove, a lifting spring with an upper end fixedly connected with the upper end wall of the lifting groove is fixed on the upper end of the electromagnetic block, four detectors with lower ends penetrating through the driving plate and positioned on the lower side of the driving plate are fixed on the lower end of the electromagnetic rod, a test tube rack is, be equipped with the intercommunication in the lift chamber right-hand member wall the lift chamber with the slip pipeline in lifting chamber, sliding connection has the left end to be located in the slip pipeline the removal pipeline in the lift intracavity, be equipped with the opening shifting chute to the left in the slip pipeline upper end wall, sliding connection has the left end to be located in the shifting chute the lift intracavity and with shifting chute left end fixed connection's L pole, still be equipped with the connection in the shifting chute right-hand member wall with the compression spring of L pole left end wall, L pole right-hand member is fixed with the right-hand member and runs through the shifting chute right end wall with lifting groove lower extreme wall and with electromagnetic block fixed connection's rope.

4. The wetland water quality chemical element measurement auxiliary collection device of claim 3, which is characterized in that: the magnetic force between the electromagnetic plate and the lifting column is larger than the sum of the elastic force of the sliding spring and the elastic force of the connecting spring, and the sliding block is provided with an inclined surface.