CN114577975A

CN114577975A - Water quality detection method

Info

Publication number: CN114577975A
Application number: CN202210338886.5A
Authority: CN
Inventors: 苏子文
Original assignee: Individual
Current assignee: Individual
Priority date: 2022-04-01
Filing date: 2022-04-01
Publication date: 2022-06-03

Abstract

The invention discloses a water quality detection method, which is scientific and reasonable in structure and comprises the following steps: s1, pumping the water to be detected, sending the water into the shunt cylinder through the water inlet pipe, making the shunt cylinder shunt the water into the connecting cylinder, S2, temporarily storing the water in the connecting cylinder through the water blocking plate, then the colorimetric drum is rotated to drive the mixing container to rotate, six samples are taken out for matching, the use is safe and convenient, the high-efficiency mixing mechanism is arranged, the transmission pinion is driven to rotate by the rotating motor, and an assembly is formed by the matching of an internal gear, the power is transmitted to drive the three transmission big gears to rotate, then the traction rope is pulled through the matching of the connecting buckles, the traction rope pulls the connecting disc to move, the stroke ejector rod and the limiting sliding frame are pushed to slide along the positioning frame, and through the characteristic that the tension spring contracts, the stroke ejector rod and the limiting sliding frame are pulled to reset, so that the stirring rotary vane is continuously driven to circularly move up and down in the stirring cylinder.

Description

Water quality detection method

Technical Field

The invention relates to the technical field of water quality detection, in particular to a water quality detection method.

Background

The water quality is closely related to the health of human beings, along with the development of social economy, scientific progress and the improvement of the living standard of people, the requirements of people on the water quality are continuously improved, and the standard of the water quality is correspondingly continuously developed and perfected;

however, in the existing water quality detection, the sampling steps are complicated, the detection efficiency is affected, and in addition, errors are easy to occur only through independent detection data, and the detection accuracy is reduced.

Disclosure of Invention

The invention provides a water quality detection method, which can effectively solve the problems that the steps of sampling in aspects such as the prior art are complicated, the detection efficiency is influenced, in addition, errors are easy to occur only through independent detection data, and the detection accuracy is reduced.

In order to achieve the purpose, the invention provides the following technical scheme: a water quality detection method comprises the following steps:

s1, pumping out the water to be detected, and sending the water into the shunt cylinder through the water inlet pipe, so that the shunt cylinder can shunt the water into the connecting cylinder;

s2, temporarily storing water in the connecting cylinder through the water plugging plate, then rotating the colorimetric rotary cylinder to drive the mixing container to rotate, and taking out six samples for use;

s3, pushing the movable push rod and the pressure push plate to move through the press ring, sending the PH detection reagent, the residual chlorine detection reagent and the calcium carbonate detection reagent in the six storage vertical plates into a mixing container for mixing, observing the mixed colors, and performing comparison recording;

s4, when water in the mixing drum above the base is increased, the floating ball, the convex plate and the sinking and floating sleeve are pushed to slide, the rotating rod and the conveying auger are driven to rotate through the matching of the spiral strip and the spiral groove, and the flocculating agent in the storage drum is conveyed into the mixing drum;

s5, starting a rotating motor to drive a transmission pinion to rotate, transmitting power through the matching of an inner gear and a transmission gear wheel, pulling a traction rope and a connecting disc, pushing a stroke ejector rod, a limiting sliding frame and a stirring rotary vane, and stirring a stirring drum up and down, so that the mixing effect is improved, and the turbidity of water is observed;

and S6, discharging the detected water, and recording the detected result.

Compared with the prior art, the invention has the beneficial effects that: the invention has scientific and reasonable structure and safe and convenient use:

1. the efficient mixing mechanism is arranged, the rotating motor drives the transmission pinion to rotate, and through the matching of an inner gear, a component is formed, power is transmitted, the three transmission gear wheels are driven to rotate, then the traction rope is pulled through the matching of the connecting buckles, the connection disc is pulled to move through the traction rope, the stroke ejector rod and the limiting sliding frame are pushed to slide along the positioning frame, the stroke ejector rod and the limiting sliding frame are pulled to reset through the contraction characteristic of the tensioning spring, the stirring rotary vanes are continuously driven to circularly move up and down in the stirring cylinder, the stirring rotary vanes are pushed to continuously rotate in the process that the stirring rotary vanes move up and down through the resistance of water, water is stirred, the water and a flocculating agent are fully mixed, then the turbidity degree of the water in the stirring cylinder is observed through the transparent sleeve, and the detection of the impurity content of the water quality is facilitated;

in addition, along with the inside water of churn increases, the surface of water promotes the floater, and through the cooperation of preventing inclined to one side slide bar, it is spacing to flange and floater, make things convenient for floater and flange area ups and downs sleeve pipe along preventing inclined to one side slide bar slip, rethread spiral strip and helicla flute cooperation, at the gliding in-process of ups and downs sleeve pipe, force the bull stick rotatory, drive and carry the auger and rotate, make the inside flocculating agent of storage silo along with the rising of the surface of water, get into the inside and water mixing of churn, the convenience of filler has been improved.

2. The device is provided with a high-efficiency colorimetric observation mechanism, the colorimetric rotary drum drives the fixing ring and the storage vertical plate to rotate, the mixing container is forced to rotate around the connecting cylinder, the waterproof sealing plate is enabled to lose the blocking of the connecting cylinder, then the characteristic of the contraction of the reset spring is passed, the stop block and the sealing slide rod are pulled to move, the waterproof sealing plate slides from the inside of the rectangular groove, the sealing of the mixing container is opened, the water in the connecting cylinder conveniently enters the mixing container to be stored, meanwhile, along with the continuous rotation of the colorimetric rotary drum, the waterproof sealing plate is pushed to contract through the matching of the arc-shaped guide plate and is embedded into the rectangular groove again, the next mixing container is enabled to move to the outer side of the water through groove, water injection is carried out again, six parts and three groups of detection samples are conveniently taken out, and the convenience of sampling is improved;

in addition, promote movable push rod and pressure push pedal through pressing the ring and remove to send into mixing container inside with the inside detect reagent of storage riser through the runner channel, make detect reagent and water mix, then contrast the colour that presents, detect PH value, chlorine residue content and the calcium carbonate content of water, contrast two sets of testing results simultaneously, improved the precision that detects.

3. The water inlet filtering mechanism is arranged, the water enters the interior of the filter cylinder through the inner pipe for primary filtering, and then the knob drives the adjusting screw to rotate, so that the waterproof plate is pushed to move to seal the inner pipe, in the moving process of the waterproof plate, the movable rod and the water retaining ring are pushed to move, the sealing of the connecting retaining ring is removed, water flows into the interior of the connecting cylinder through the other connecting rod for secondary filtering, a water quality detection flow channel is adjusted twice, the interference is prevented, the detection accuracy is ensured, and the impurity content in the water is detected by observing the impurity residue on the PP cotton;

in addition, water is temporarily stored in the connecting cylinder through the water plugging plate, when the water in the connecting cylinder increases, the water surface rises to push the floating plate to rise, so that the floating plate can rise through the lifting slide bar to pull the water plugging plate to remove the sealing of the connecting cylinder, the water is conveniently conveyed into the stirring cylinder, and the convenience is improved.

Synthesize, through intaking filter mechanism and high-efficient color comparison observation mechanism cooperation, at the in-process of sending water, take out six samples from the aquatic, conveniently detect aquatic PH value, chlorine residue content and calcium carbonate content to through the contrast of two sets of data, improve the precision that detects, increase the mixed effect of flocculating agent and water through high-efficient mixing mechanism simultaneously, make things convenient for impurity to gather together, further detect the impurity of quality of water, prevent that the error from appearing，The detection result is ensured.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention.

In the drawings:

FIG. 1 is a flow chart of the detection method of the present invention;

FIG. 2 is a schematic view of the mounting structure of the mixing drum of the present invention;

FIG. 3 is a schematic structural view of the high efficiency mixing mechanism of the present invention;

FIG. 4 is a schematic view of the installation structure of the helical strip of the present invention;

FIG. 5 is a schematic view of the installation configuration of the pull-cord of the present invention;

FIG. 6 is a schematic view of the mounting structure of the tension spring of the present invention;

FIG. 7 is a schematic view of the installation structure of the bump stopper of the present invention;

FIG. 8 is a schematic diagram of the structure of the high efficiency colorimetric observation mechanism of the present invention;

fig. 9 is a schematic structural view of the influent water filtering mechanism of the present invention.

Reference numbers in the figures: 1. a base; 2. a mixing drum;

3. a high efficiency mixing mechanism; 301. a positioning frame; 302. a reciprocating slip ring; 303. stirring the rotary blade; 304. a limiting sliding frame; 305. a tension spring; 306. a stroke ejector rod; 307. a connecting disc; 308. a hauling rope; 309. a driving gearwheel; 310. a connecting buckle; 311. an internal gear; 312. a connecting plate; 313. a rotating electric machine; 314. a drive pinion; 315. a transparent sleeve; 316. a storage cylinder; 317. positioning a top plate; 318. a rotating rod; 319. conveying the auger; 320. sinking and floating the sleeve; 321. a helical strip; 322. a helical groove; 323. a convex plate; 324. a floating ball; 325. a deviation-preventing slide bar;

4. a high-efficiency colorimetric observation mechanism; 401. a connecting cylinder; 402. a colorimetric drum; 403. a fixing ring; 404. storing the vertical plate; 405. a movable push rod; 406. pressing a ring; 407. a pressure push plate; 408. a mixing vessel; 409. a circulation tank; 410. an L-shaped slide plate; 411. sealing the baffle; 412. sealing the sliding rod; 413. a stopper; 414. a return spring; 415. a rectangular groove; 416. a waterproof sealing plate; 417. a water trough; 418. an arc-shaped guide plate;

5. a water inlet filtering mechanism; 501. a filter cartridge; 502. a water inlet pipe; 503. filtering with a screen; 504. a shunt cylinder; 505. adjusting the screw rod; 506. a knob; 507. a waterproof sheet; 508. connecting a baffle ring; 509. an inner tube; 510. a movable rod; 511. a water retaining ring; 512. PP cotton; 513. a mounting frame; 514. lifting the sliding rod; 515. a limit stop block; 516. a floating plate; 517. a water plugging plate.

Detailed Description

The preferred embodiments of the present invention will be described in conjunction with the accompanying drawings, and it will be understood that they are described herein for the purpose of illustration and explanation and not limitation.

The embodiment is as follows: as shown in fig. 1, the invention provides a technical scheme, and a water quality detection method comprises the following steps:

s1, pumping out the water to be detected, and sending the water into the shunt cylinder 504 through the water inlet pipe 502, so that the shunt cylinder 504 can shunt the water into the connecting cylinder 401;

s2, temporarily storing water in the connecting cylinder 401 through the water blocking plate 517, then rotating the colorimetric cylinder 402 to drive the mixing container 408 to rotate, and taking out six samples for use;

s3, pushing the movable push rod 405 and the pressure push plate 407 to move through the press ring 406, sending the PH detection reagent, the residual chlorine detection reagent and the calcium carbonate detection reagent in the six storage vertical plates 404 into the mixing container 408 for mixing, observing the mixed colors, and performing comparison recording;

s4, when the water in the mixing drum 2 above the base 1 is increased, the floating ball 324, the convex plate 323 and the sinking and floating sleeve 320 are pushed to slide, and the rotating rod 318 and the conveying auger 319 are driven to rotate through the matching of the spiral strip 321 and the spiral groove 322, so that the flocculating agent in the storage drum 316 is conveyed into the mixing drum 2;

s5, starting a rotating motor 313 to drive a transmission pinion 314 to rotate, transmitting power through the matching of an internal gear 311 and a transmission large gear 309, pulling a traction rope 308 and a connecting disc 307, pushing a stroke ejector rod 306, a limiting sliding frame 304 and a stirring rotary vane 303, and stirring the stirring drum 2 up and down, so that the mixing effect is improved, and the turbidity of water is observed;

s6, discharging the detected water, and recording the detected result;

as shown in fig. 2-9, a water quality detection device, a mixing drum 2 is clamped at the top end of a base 1, a high-efficiency mixing mechanism 3 is arranged inside the mixing drum 2, the high-efficiency mixing mechanism 3 comprises a positioning frame 301, a reciprocating slip ring 302, a mixing rotary vane 303, a limiting sliding frame 304, a tensioning spring 305, a stroke ejector rod 306, a connecting disc 307, a traction rope 308, a transmission big gear 309, a connecting buckle 310, an internal gear 311, a connecting plate 312, a rotary motor 313, a transmission small gear 314, a transparent sleeve 315, a storage drum 316, a positioning top plate 317, a rotary rod 318, a conveying auger 319, a sinking and floating sleeve 320, a spiral strip 321, a spiral groove 322, a convex plate 323, a floating ball 324 and an anti-deflection sliding rod 325;

a positioning frame 301 is clamped in the stirring barrel 2, a reciprocating sliding ring 302 is movably sleeved on the outer side of the positioning frame 301, a stirring rotary blade 303 is rotatably connected to the outer side of the reciprocating sliding ring 302, a limiting sliding frame 304 is clamped on the inner wall of the reciprocating sliding ring 302 corresponding to the inner part of the positioning frame 301, a tensioning spring 305 is clamped on the top end of the limiting sliding frame 304 corresponding to the inner part of the positioning frame 301, a stroke ejector rod 306 is clamped at the bottom end of the limiting sliding frame 304 corresponding to the inner part of the positioning frame 301, a connecting disc 307 is fixedly connected to the bottom end of the stroke ejector rod 306 corresponding to the bottom of the stirring barrel 2 through bolts, and traction ropes 308 are clamped on the top end of the connecting disc 307 at equal intervals;

the bottom end of the mixing drum 2 is connected with a transmission big gear 309 in an equidistant rotating way at the position corresponding to the inner part of the base 1, a connecting buckle 310 is connected at the position of one side of the bottom end of the transmission big gear 309 in a rotating way, the bottom end of the connecting buckle 310 is clamped with the other end of the traction rope 308, an inner gear 311 is connected at the position corresponding to the outer side of the transmission big gear 309 at the outer side of the mixing drum 2 in a rotating way, a connecting plate 312 is fixedly connected at the bottom end of the mixing drum 2 through a bolt, a rotating motor 313 is fixedly connected at one end of the connecting plate 312 through a bolt, a transmission small gear 314 is fixedly sleeved at the position corresponding to the inner side of the inner gear 311 at the output shaft of the rotating motor 313, in order to improve the mixing effect, the mixing rotary vane 303 is obliquely arranged at the outer side of the reciprocating slip ring 302, waterproof paint is coated at the outer side of the tensioning spring 305, the transmission big gear 309 is mutually meshed with the inner gear 311, the transmission small gear 314 is mutually meshed with the inner gear 311, the diameter of the transmission big gear 309 is equal to the length of the traction rope 308, the rotating electric machine 313 is supplied with power by an external power supply;

a transparent sleeve 315 is clamped at the outer side of the stirring cylinder 2, a storage cylinder 316 is clamped at the top end of the stirring cylinder 2 corresponding to one side of the connecting cylinder 401, a positioning top plate 317 is clamped at the top position of the inner wall of the storage cylinder 316, a rotating rod 318 is rotatably connected at the bottom end of the positioning top plate 317, a conveying auger 319 is fixedly sleeved at the outer side of the rotating rod 318 corresponding to the inner side of the storage cylinder 316, a sinking and floating sleeve 320 is movably sleeved at the outer side of the rotating rod 318 corresponding to the inner position of the stirring cylinder 2, a spiral strip 321 is clamped at the outer side of the rotating rod 318 corresponding to the inner position of the stirring cylinder 2, a spiral groove 322 is formed at the inner wall of the sinking and floating sleeve 320 corresponding to the outer side of the spiral strip 321, a convex plate 323 is fixedly connected at one end of the sinking and floating sleeve 320 through a bolt, a floating ball 324 is clamped at one end of the convex plate 323, an anti-deflection sliding rod 325 is movably connected at the inner wall of the convex plate 323, a flocculating agent is filled in the storage cylinder 316 for facilitating the collection of impurities, an anti deflection bracket is clamped at the bottom position of the inner wall of the storage cylinder 316, the inner wall of the deviation-proof support is rotationally connected with the outer side of the rotating rod 318, the spiral strip 321 is in sliding connection with the spiral groove 322, and the top end of the deviation-proof sliding rod 325 is clamped with the top end of the stirring cylinder 2;

the high-efficiency colorimetric observation mechanism 4 comprises a connecting cylinder 401, a colorimetric rotating cylinder 402, a fixing ring 403, a storage vertical plate 404, a movable push rod 405, a pressing ring 406, a pressure push plate 407, a mixing container 408, a circulating groove 409, an L-shaped sliding plate 410, a sealing baffle 411, a sealing slide bar 412, a stop 413, a return spring 414, a rectangular groove 415, a waterproof sealing plate 416, a water circulating groove 417 and an arc-shaped guide plate 418;

the top end of the mixing drum 2 is connected with a connecting drum 401 through a screw thread, the outer side of the connecting drum 401 is rotationally connected with a colorimetric rotating drum 402, the bottom position of the outer side of the colorimetric rotating drum 402 is fixedly sleeved with a fixed ring 403, the top end of the fixed ring 403 is clamped with a storage vertical plate 404 at the position corresponding to the outer side position of the colorimetric rotating drum 402 at equal intervals, the top end of the storage vertical plate 404 is symmetrically and slidably connected with a movable push rod 405, the top end of the movable push rod 405 is clamped with a press ring 406 at the position corresponding to the outer side position of the colorimetric rotating drum 402, the bottom end of the movable push rod 405 is clamped with a pressure push plate 407 at the position corresponding to the inner part of the storage vertical plate 404, in order to collect samples conveniently, the joint of the colorimetric drum 402 and the connecting cylinder 401 is filled with a sealed waterproof rubber ring, the storage risers 404 are six in total, two groups of PH detection reagents, two groups of residual chlorine detection reagents and two groups of calcium carbonate detection reagents are stored in the six storage vertical plates 404, and through holes are formed in the inner wall of the colorimetric rotary drum 402 and the inner wall of the rectangular groove 415;

a mixing container 408 is clamped between every two adjacent storage vertical plates 404, circulation grooves 409 are formed in one ends of the mixing containers 408 and one ends of the storage vertical plates 404, L-shaped sliding plates 410 are movably connected to the top and bottom positions of the inner walls of the circulation grooves 409, and sealing baffles 411 are clamped at positions, corresponding to the inner positions of the mixing containers 408, of one ends of the L-shaped sliding plates 410;

sealing slide bars 412 are symmetrically and slidably connected to positions, corresponding to the top end and the bottom of the mixing container 408, on the outer side of the colorimetric rotary drum 402, a stopper 413 is welded to one end of each sealing slide bar 412, a return spring 414 is clamped between one end of each stopper 413 and a position, corresponding to the outer side of the sealing slide bar 412, on the outer side of the colorimetric rotary drum 402, a rectangular groove 415 is formed in a position, corresponding to the inner side of the mixing container 408, on the inner wall of the connecting cylinder 401, a waterproof sealing plate 416 is clamped to a position, corresponding to the inner portion of the rectangular groove 415, on the other end of each sealing slide bar 412, a water through groove 417 is formed in the inner wall of the connecting cylinder 401, arc-shaped guide plates 418 are symmetrically clamped to the inner wall of the water through groove 417, in order to avoid a sealing effect, magnetic cores are embedded in the inner portions of the L-shaped sliding plates 410 and the inner walls of the storage risers 404, and the two opposite magnetic cores are mutually exclusive, the length and the width of the sealing baffle 411 are both greater than the length and the width of the inner wall of the circulation groove 409, the mixing container 408 is made of acrylic plates, the inner wall of the colorimetric cylinder 402 is tightly attached to the outer side of the connecting cylinder 401, and the waterproof sealing plate 416 is made of waterproof rubber;

the top end of the connecting cylinder 401 is provided with a water inlet filtering mechanism 5, and the water inlet filtering mechanism 5 comprises a filter cylinder 501, a water inlet pipe 502, a filter screen 503, a flow distribution cylinder 504, an adjusting screw 505, a knob 506, a waterproof plate 507, a connecting baffle ring 508, an inner pipe 509, a movable rod 510, a water retaining ring 511, PP cotton 512, a mounting frame 513, a lifting slide rod 514, a limit stop 515, a floating plate 516 and a water blocking plate 517;

the top end of the connecting cylinder 401 is connected with a filter cylinder 501 through screw threads, the inner wall of the filter cylinder 501 is equidistantly clamped with filter screens 503, the top end of the filter cylinder 501 is connected with a shunt cylinder 504 through screw threads, one end of the shunt cylinder 504 is clamped with a water inlet pipe 502, the top end of the shunt cylinder 504 is rotatably connected with an adjusting screw 505, the top end of the adjusting screw 505 is welded with a knob 506, the outer side of the adjusting screw 505 is connected with a waterproof plate 507 through screw threads, the top position of the inner wall of the connecting cylinder 401 is clamped with a connecting baffle ring 508, the inner wall of the connecting baffle ring 508 is clamped with an inner pipe 509, the top end of the connecting baffle ring 508 is equidistantly clamped with a movable rod 510, the bottom end of the movable rod 510 is clamped with a water baffle ring 511 corresponding to the bottom position of the connecting baffle ring 508, the top end of the movable rod 510 is clamped with the bottom end of the waterproof plate 507, the inner wall of the inner pipe 509 and the outer side of the inner pipe 509 are clamped with PP cotton 512 corresponding to the inner positions of the two filter screens 503, in order to improve the waterproof effect, the joint of the connecting cylinder 401 and the filter cylinder 501 is filled with waterproof rubber, the joint of the filter cylinder 501 and the flow distribution cylinder 504 is filled with waterproof rubber, and the bottom end of the inner pipe 509 penetrates through one filter screen 503 and is attached to the top end of the other filter screen 503;

connecting pipe 401 inner wall top and the equal joint in bottom position department have mounting bracket 513, two mounting bracket 513 inner walls all rotate and are connected with lift slide bar 514, and the equal butt fusion of lift slide bar 514 top and bottom has spacing dog 515, lift slide bar 514 outside top position department is fixed to have cup jointed kickboard 516, the fixed water shutoff board 517 that has cup jointed in lift slide bar 514 outside bottom position department, in order to protect the leakproofness, the diameter of manger plate ring 511 is greater than the distance between the ring 508 inner wall of connecting fender, the movable rod 510 top through connection keeps off ring 508 and waterproof board 507 bottom looks joint, water shutoff board 517 bottom begins to have the inclined plane, and the inclined plane of water shutoff board 517 bottom is laminated mutually with the inner wall of connecting cylinder 401.

The working principle and the using process of the invention are as follows: firstly, water is conveniently sent into the interior of the flow dividing cylinder 504 through the water inlet pipe 502, the water enters the interior of the filter cylinder 501 through the inner pipe 509, meanwhile, the water is filtered through the PP cotton 512, impurities in the water are stored in the interior of the PP cotton 512, the filtered water enters the interior of the connecting cylinder 401 through the filter cylinder 501, when the water enters the interior of the connecting cylinder 401, the water is temporarily stored in the interior of the connecting cylinder 401 through the cooperation of the water blocking plate 517, when the water in the interior of the connecting cylinder 401 increases, the water surface rises to push the floating plate 516 to rise, so that the floating plate 516 pulls the water blocking plate 517 to rise through the lifting slide rod 514, the sealing of the connecting cylinder 401 is released, and the water is conveniently sent into the interior of the stirring cylinder 2;

then, the knob 506 is rotated to drive the knob 506 to rotate with the adjusting screw 505, so that the waterproof board 507 is pushed to move to seal the inner pipe 509, meanwhile, in the moving process of the waterproof board 507, the water retaining ring 511 is pushed to move through the matching of the movable rod 510, the sealing of the connecting baffle ring 508 is released, water flows into the connecting cylinder 401 through the other connecting rod, meanwhile, the water is filtered again through the other PP cotton 512, and the detection effect on the water quality is improved by comparing impurities on the two PP cotton 512;

then, when the water inside the connecting cylinder 401 is stored more, the rotating colorimetric cylinder 402 is rotated to rotate the colorimetric cylinder 402 with the fixing ring 403 and the storage vertical plate 404, the mixing container 408 is forced to rotate around the connecting cylinder 401, and the waterproof sealing plate 416 is released from the blocking of the connecting cylinder 401, then, by the property of the retraction of the return spring 414, the stopper 413 is pulled, so that the stopper 413 pushes the sealing slide rod 412 to move, the waterproof sealing plate 416 is forced to slide from the inside of the rectangular groove 415, the sealing of the mixing container 408 is opened, water in the connecting cylinder 401 can enter the inside of the mixing container 408 for storage, and with the continuous rotation of the color comparison rotating cylinder 402, through the cooperation of the arc-shaped guide plate 418, the waterproof sealing plate 416 is pushed to shrink, is embedded into the rectangular groove 415 again, the next mixing container 408 is moved to the outside of the water passing tank 417, water is injected again, and six detection samples are taken out conveniently;

then, the movable push rod 405 and the pressure push plate 407 are pushed by the pressing ring 406 to move, so that the detection reagent in the storage vertical plate 404 is sent into the mixing container 408 through the circulation groove 409, the detection reagent is mixed with water, the presented colors are compared, the pH value, the residual chlorine content and the calcium carbonate content of the water are detected, and meanwhile, the two groups of detection results are compared, so that the detection accuracy is improved;

then, after water enters the mixing drum 2, a rotating motor 313 is started, the rotating motor 313 drives a transmission pinion 314 to rotate, meanwhile, through the matching of an inner gear 311, a component is formed, power is transmitted, three transmission large gears 309 are driven to rotate, then through the matching of a connecting buckle 310, a traction rope 308 is pulled, the traction rope 308 pulls a connecting disc 307 to move, a stroke ejector rod 306 and a limiting sliding frame 304 are pushed to slide along a positioning frame 301, meanwhile, through the contraction characteristic of a tension spring 305, the stroke ejector rod 306 and the limiting sliding frame 304 are pulled to reset, the mixing rotary vane 303 is continuously driven to circularly move up and down in the mixing drum 2 in a reciprocating mode, in the process that the mixing rotary vane 303 moves up and down through the resistance of water, the mixing rotary vane 303 is pushed to continuously rotate, water is mixed fully, then, the turbidity degree of the water in the mixing drum is observed through a transparent sleeve 315, detecting the impurity content of the water quality;

finally, as the water inside the mixing drum 2 increases, the water surface pushes the floating ball 324, and meanwhile, the convex plate 323 and the floating ball 324 are limited through the matching of the deviation-preventing slide rod 325, so that the floating ball 324 and the convex plate 323 can bring the sinking and floating sleeve 320 to slide along the deviation-preventing slide rod 325 conveniently, and the spiral strip 321 is matched with the spiral groove 322, and in the sliding process of the sinking and floating sleeve 320, the rotating rod 318 is forced to rotate, so that the conveying auger 319 is driven to rotate, and the flocculating agent inside the storage drum 316 enters the mixing drum 2 to be mixed with the water along with the rising of the water surface, thereby improving the convenience of filling.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that changes may be made in the embodiments and/or equivalents thereof without departing from the spirit and scope of the invention. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims

1. A water quality detection method is characterized in that: the method comprises the following steps:

s1, pumping out the water to be detected, and sending the water into the shunt cylinder (504) through the water inlet pipe (502) to make the shunt cylinder (504) shunt the water into the connecting cylinder (401);

s2, temporarily storing water in the connecting cylinder (401) through the water blocking plate (517), then rotating the colorimetric rotating cylinder (402) to drive the mixing container (408) to rotate, and taking out six samples for use;

s3, pushing the movable push rod (405) and the pressure push plate (407) to move through the pressing ring (406), sending the PH detection reagent, the residual chlorine detection reagent and the calcium carbonate detection reagent in the six storage vertical plates (404) into a mixing container (408) for mixing, observing the mixed colors, and performing comparison recording;

s4, when water in the mixing drum (2) above the base (1) increases, the floating ball (324), the convex plate (323) and the sinking-floating sleeve (320) are pushed to slide, and the rotating rod (318) and the conveying auger (319) are driven to rotate through the matching of the spiral strip (321) and the spiral groove (322), so that the flocculating agent in the storage drum (316) is conveyed into the mixing drum (2);

s5, starting a rotating motor (313) to drive a transmission pinion (314) to rotate, transmitting power through the matching of an internal gear (311) and a transmission large gear (309), pulling a traction rope (308) and a connecting disc (307), pushing a stroke ejector rod (306), a limiting sliding frame (304) and a stirring rotary vane (303), and stirring the stirring barrel (2) up and down, so that the mixing effect is improved, and the turbidity of water is observed;

and S6, discharging the detected water, and recording the detected result.

2. A water quality detecting method according to claim 1, characterized in that: the top end of the base (1) is clamped with a stirring barrel (2), a high-efficiency mixing mechanism (3) is arranged inside the stirring barrel (2), and the high-efficiency mixing mechanism (3) comprises a positioning frame (301), a reciprocating slip ring (302), a stirring rotary vane (303), a limiting sliding frame (304), a tensioning spring (305), a stroke ejector rod (306), a connecting disc (307), a traction rope (308), a transmission large gear (309), a connecting buckle (310), an internal gear (311), a connecting plate (312), a rotating motor (313), a transmission small gear (314), a transparent sleeve (315), a storage barrel (316), a positioning top plate (317), a rotary rod (318), a conveying auger (319), a sinking and floating sleeve (320), a spiral strip (321), a spiral groove (322), a convex plate (323), a floating ball (324) and an anti-deflection slide rod (325);

a positioning frame (301) is clamped in the stirring barrel (2), a reciprocating sliding ring (302) is movably sleeved on the outer side of the positioning frame (301), a stirring rotary vane (303) is rotatably connected to the outer side of the reciprocating sliding ring (302), a limiting sliding frame (304) is clamped in the inner wall of the reciprocating sliding ring (302) corresponding to the positioning frame (301), a tensioning spring (305) is clamped at the position of the top end of the limiting sliding frame (304) corresponding to the inner position of the positioning frame (301), a stroke ejector rod (306) is clamped in the bottom end of the limiting sliding frame (304) corresponding to the inner part of the positioning frame (301), a connecting disc (307) is fixedly connected at the position of the bottom end of the stroke ejector rod (306) corresponding to the bottom of the stirring barrel (2) through bolts, and traction ropes (308) are clamped at equal intervals at the top end of the connecting disc (307);

the bottom end of the stirring cylinder (2) is connected with a transmission large gear (309) in an equidistant rotating mode at a position corresponding to the inner part of the base (1), a connecting buckle (310) is connected at a position on one side of the bottom end of the transmission large gear (309) in a rotating mode, the bottom end of the connecting buckle (310) is connected with the other end of the traction rope (308) in a clamping mode, an inner gear (311) is connected at a position, corresponding to the outer side of the transmission large gear (309), on the outer side of the stirring cylinder (2) in a rotating mode, the bottom end of the stirring cylinder (2) is fixedly connected with a connecting plate (312) through bolts, one end of the connecting plate (312) is fixedly connected with a rotating motor (313) through bolts, and a transmission small gear (314) is fixedly sleeved at a position, corresponding to the inner side of the inner gear (311), of an output shaft of the rotating motor (313);

the outer side of the mixing drum (2) is connected with a transparent sleeve (315) in a clamped manner, the top end of the mixing drum (2) is connected with a storage drum (316) in a clamped manner corresponding to one side position of a connecting drum (401), the top position of the inner wall of the storage drum (316) is connected with a positioning top plate (317), the bottom end of the positioning top plate (317) is rotatably connected with a rotating rod (318), the outer side of the rotating rod (318) is fixedly sleeved with a conveying auger (319) corresponding to the inner side position of the storage drum (316), the outer side of the rotating rod (318) is movably sleeved with a sinking and floating sleeve (320) corresponding to the inner side position of the mixing drum (2), the outer side of the rotating rod (318) is connected with a spiral strip (321) in a clamped manner corresponding to the inner position of the mixing drum (2), a spiral groove (322) is formed in the position of the inner wall of the sinking and floating sleeve (320) corresponding to the outer side position of the spiral strip (321), one end of the sinking and floating sleeve (320) is fixedly connected with a convex plate (323) through a bolt, one end of the convex plate (323) is clamped with a floating ball (324), and the inner wall of the convex plate (323) is movably connected with an anti-deflection sliding rod (325).

3. A water quality detecting method according to claim 2, characterized in that: stirring vane (303) slope is installed and is come and go the sliding ring (302) outside, waterproof coating has been paintd on tensioning spring (305) outside, transmission gear wheel (309) and internal gear (311) intermeshing, transmission pinion (314) and internal gear (311) intermeshing, the diameter of transmission gear wheel (309) equals the length of haulage rope (308), rotating electrical machines (313) supply power through external power source.

4. A water quality detecting method according to claim 2, characterized in that: storage cylinder (316) inside packing has the flocculating agent, storage cylinder (316) inner wall bottom position department joint has prevents inclined to one side support, prevent inclined to one side support inner wall and bull stick (318) outside and rotate and be connected, spiral strip (321) and helicla flute (322) sliding connection, prevent inclined to one side slide bar (325) top and churn (2) top end joint.

5. A water quality detecting method according to claim 2, characterized in that: the high-efficiency colorimetric observation mechanism (4) comprises a connecting cylinder (401), a colorimetric rotating cylinder (402), a fixing ring (403), a storage vertical plate (404), a movable push rod (405), a pressing ring (406), a pressure push plate (407), a mixing container (408), a circulating groove (409), an L-shaped sliding plate (410), a sealing baffle plate (411), a sealing sliding rod (412), a stop block (413), a return spring (414), a rectangular groove (415), a waterproof sealing plate (416), a water through groove (417) and an arc guide plate (418);

the top end of the stirring cylinder (2) is connected with a connecting cylinder (401) through threads, the outer side of the connecting cylinder (401) is rotatably connected with a colorimetric rotating cylinder (402), a fixing ring (403) is fixedly sleeved at the position of the bottom of the outer side of the colorimetric rotating cylinder (402), storage risers (404) are clamped at the positions, corresponding to the outer side of the colorimetric rotating cylinder (402), of the top end of the fixing ring (403) at equal intervals, movable push rods (405) are symmetrically and slidably connected to the top end of the storage risers (404), pressing rings (406) are clamped at the positions, corresponding to the outer side of the colorimetric rotating cylinder (402), of the top end of the movable push rod (405), and pressure push plates (407) are clamped at the positions, corresponding to the inner part of the storage risers (404), of the bottom end of the movable push rod (405);

a mixing container (408) is clamped between every two adjacent storage vertical plates (404), circulation grooves (409) are formed in one end of each mixing container (408) and one end of each storage vertical plate (404), L-shaped sliding plates (410) are movably connected to the top and the bottom of the inner wall of each circulation groove (409), and sealing baffles (411) are clamped at positions, corresponding to the inner positions of the mixing containers (408), of one ends of the L-shaped sliding plates (410);

the equal symmetrical sliding connection in colorimetric rotary drum (402) outside correspondence mixing container (408) top and bottom position department has sealed slide bar (412), the butt fusion of sealed slide bar (412) one end has dog (413), and dog (413) one end and colorimetric rotary drum (402) outside correspond sealed slide bar (412) outside position department and all connect and have reset spring (414), rectangular channel (415) have been seted up in connecting cylinder (401) inner wall correspondence mixing container (408) inboard position department, and sealed slide bar (412) other end corresponds rectangular channel (415) inside position department joint and has waterproof sealing plate (416), water passing groove (417) have been seted up to connecting cylinder (401) inner wall, water passing groove (417) inner wall symmetry joint has arc baffle (418).

6. A water quality detecting method according to claim 5, characterized in that: the sealed waterproof rubber ring is filled in the junction of color comparison rotary drum (402) and connecting cylinder (401), storage riser (404) are total six, and six storage risers (404) have two sets of PH detect reagent, two sets of chlorine residue detect reagent and two sets of calcium carbonate detect reagent of storing altogether, through-hole has all been seted up to color comparison rotary drum (402) inner wall and rectangular channel (415) inner wall.

7. A water quality detecting method according to claim 5, characterized in that: the utility model discloses a color comparison rotary drum, including L type slide (410), the inside magnetic core of all installing of L type slide (410) and inside all embedding of storage riser (404) inner wall, and two relative magnetic cores repel each other, the length and the width of seal baffle (411) all are greater than the length and the width of circulation groove (409) inner wall, mixing vessel (408) are made through the ya keli board, closely laminate in color comparison rotary drum (402) inner wall and connecting cylinder (401) outside, waterproof sealing plate (416) are made for waterproof rubber.

8. A water quality detecting method according to claim 5, characterized in that: the water inlet filtering mechanism (5) is arranged at the top end of the connecting cylinder (401), and the water inlet filtering mechanism (5) comprises a filter cylinder (501), a water inlet pipe (502), a filter screen (503), a shunt cylinder (504), an adjusting screw (505), a knob (506), a waterproof plate (507), a connecting baffle ring (508), an inner pipe (509), a movable rod (510), a water retaining ring (511), PP cotton (512), a mounting frame (513), a lifting slide rod (514), a limit stop (515), a floating plate (516) and a water blocking plate (517);

the top end of the connecting cylinder (401) is connected with a filter cylinder (501) through threads, a filter screen (503) is connected to the equidistant joint of the inner wall of the filter cylinder (501), the top end of the filter cylinder (501) is connected with a shunt cylinder (504) through threads, a water inlet pipe (502) is connected to one end of the shunt cylinder (504), the top end of the shunt cylinder (504) is rotatably connected with an adjusting screw (505), a knob (506) is welded to the top end of the adjusting screw (505), a waterproof plate (507) is connected to the outer side of the adjusting screw (505) through threads, a connecting baffle ring (508) is connected to the top position joint of the inner wall of the connecting cylinder (401), an inner pipe (509) is connected to the inner wall joint of the connecting baffle ring (508), a movable rod (510) is connected to the equidistant joint of the top end of the connecting baffle ring (508), a water retaining ring (511) is connected to the bottom position joint of the connecting baffle ring (508), the top end of the movable rod (510) is clamped with the bottom end of the waterproof plate (507), and PP cotton (512) is clamped on the inner wall of the inner pipe (509) and the outer side of the inner pipe (509) corresponding to the inner positions of the two filter screens (503);

connecting pipe (401) inner wall top and the equal joint in bottom position department have mounting bracket (513), two mounting bracket (513) inner wall all rotates and is connected with lift slide bar (514), and all welds spacing dog (515) on lift slide bar (514) top and bottom, lift slide bar (514) outside top position department is fixed to be cup jointed kickboard (516), the fixed water shutoff board (517) that has cup jointed of lift slide bar (514) outside bottom position department.

9. The water quality detection method according to claim 8, characterized in that: the junction of connecting cylinder (401) and cartridge filter (501) is filled with waterproof rubber, the junction of cartridge filter (501) and reposition of redundant personnel section of thick bamboo (504) is filled with waterproof rubber, inner tube (509) bottom is run through a filter screen (503) and is laminated mutually with another filter screen (503) top.

10. A water quality detecting method according to claim 8, characterized in that: the diameter of manger plate ring (511) is greater than and connects the distance between fender ring (508) inner wall, movable rod (510) top run-through connection keeps off ring (508) and waterproof board (507) bottom end joint, water shutoff board (517) bottom begins to have the inclined plane, and the inclined plane of water shutoff board (517) bottom is laminated with the inner wall of connecting cylinder (401) mutually.