CN115615793A

CN115615793A - Sampling screen filter for hyperspectral water quality detection

Info

Publication number: CN115615793A
Application number: CN202211620012.5A
Authority: CN
Inventors: 祝青; 秦静
Original assignee: Xi'an Zhongkexiguang Aerospace Technology Co ltd
Current assignee: Xi'an Zhongkexiguang Aerospace Technology Co ltd
Priority date: 2022-12-16
Filing date: 2022-12-16
Publication date: 2023-01-17
Anticipated expiration: 2042-12-16
Also published as: CN115615793B

Abstract

The invention discloses a sampling screen filter for hyperspectral water quality detection, which relates to the technical field of sampling screening, and comprises a top cover, a shell, a backflow device, a first screening device, a flow limiting device, a second screening device, a detection device and a collection device, wherein the bottom of the top cover is fixedly connected to the top of the backflow device, the surface of the backflow device is inserted into the first screening device, the top of the first screening device is fixedly connected to the bottom of a through hole formed in the surface of the top shell, the top of the shell is fixedly connected to the bottom of the top shell, and the bottom of the first screening device is fixedly connected to the top of the flow limiting device. This high spectrum water quality testing is with sample sieve filter reaches the effect of guaranteeing to detect the accuracy to the backward flow of rivers, when rivers were too big, plays increase rivers and sieve the contact time between die sleeve and the adhesion post, prevents in addition that rivers from blockking up accumulational effect.

Description

Sampling screen filter for hyperspectral water quality detection

Technical Field

The invention relates to the technical field of sampling, screening and filtering, in particular to a sampling, screening and filtering device for hyperspectral water quality detection.

Background

Screen filters, devices that pass liquid through a screen by gravity, are commonly used for dewatering, and multi-layer screens may also be used for classification.

The suspension containing the particles or flocculates is passed through a screen without clogging the screen, often aided by vibration or other means of movement.

The existing sampling sieve filter for water quality detection still has the problem that when water is detected, a small amount of water often flows out from an injection port to influence the overall detection precision, and the traditional sieve filter often pours water into the traditional sieve filter and separates precipitates in the water by a dehydration method, so that the method can only deposit a small amount of impurities in the water, and meanwhile, the efficiency is lower. In addition, in water quality detection, when water flows too much or accumulates, strong pressure can be generated on the instrument, and the instrument is possibly damaged.

Disclosure of Invention

In order to realize the purpose, the invention is realized by the following technical scheme: the utility model provides a hyperspectral water quality testing is with sample sieve filter, includes top cap, shell, reflux unit, a sieve and strains device, current limiting device, no. two sieves and strains device, detection device and collection device.

The bottom of the top cover is fixedly connected to the top of the backflow device, the surface of the backflow device is inserted into the first screening device, the top of the first screening device is fixedly connected to the bottom of a through hole formed in the surface of the top shell, the top of the shell is fixedly connected to the bottom of the top shell, the bottom of the first screening device is fixedly connected to the top of the flow limiting device, the bottom of the flow limiting device is fixedly connected to the top of the second screening device, the bottom of the second screening device is fixedly connected to the top of the detection device, the bottom of the detection device is fixedly connected to the top of the collection device, and the outer surface of the collection device is fixedly connected to the inner wall of the shell;

the backflow device comprises a hollow ring plate, the surface of the top cover is provided with a ring-shaped hole, the bottom of the top cover is fixedly connected to the top of the hollow ring plate, the top of the hollow ring plate faces the ring-shaped hole, one end, far away from the top cover, of the hollow ring plate is fixedly connected with a backflow pipe, the surface of the backflow pipe is inserted into the first screening device in a penetrating mode, and the hollow ring plate and the backflow pipe play a backflow role;

the device is strained to first sieve includes the sieve filter, the bottom fixedly connected with cover of sieve filter is equipped with the pressure relief ware, the sieve filter strains the die sleeve including the sieve, the top fixed connection of die sleeve is in the bottom of top cap in the sieve, the first section fixedly connected with connecting rod of die sleeve inner wall is strained to the sieve, the one end fixedly connected with that the die sleeve was strained to the sieve is kept away from to the connecting rod glues and adheres the post, the surface sliding connection who adheres the post has auger blade, and wherein auger blade's effect is the area of contact between increase rivers and the sieve die sleeve to the increase is strained the effect to the sieve of quality of water, one side sliding connection that auger blade kept away from to glue the post is on the inner wall of die sleeve is strained to the sieve, the outside fixedly connected with connecting plate of the second section of auger blade, the bottom fixedly connected with circulation base of connecting plate.

Preferably, the pressure relief device is including releasing the pressure tank, the bottom fixed connection in the top of current limiting device of releasing the pressure tank, the inner wall sliding connection who releases the pressure tank has the trompil board, the inner wall sliding connection of the first half section of trompil board is in the outside of sieve filter die sleeve lower extreme, the pressure release hole has been seted up on the surface of trompil board department of buckling, the last fixed surface of trompil board is connected with the absorption sponge, and wherein adsorb the sponge and not only play the effect of adsorbing aquatic impurity, still play and leave a silk space when letting circulation base and trompil board fold and let rivers pass through, prevent that rivers from blockking up accumulational effect.

Preferably, the current limiting device comprises an inner sliding sleeve, the top of the inner sliding sleeve is fixedly connected to the bottom of the pressure relief groove, the outer surface of the inner sliding sleeve is connected with a sliding shell in a sliding manner, and the outer surface of the sliding shell is connected with a current limiting shell in a sliding manner.

Preferably, the inner wall of the inner sliding sleeve is fixedly connected with a sliding rod, the bottom of the sliding rod is fixedly connected with a check ring, the surface of the sliding rod is connected with a movable plate in a sliding mode, the surface of the movable plate is sleeved with a vertical pipe, and the vertical pipe penetrates through the surface of the movable plate and extends to the outside.

Preferably, the bottom of the sliding shell is fixedly connected with an extrusion plate, and the upper side and the lower side of the inner wall of the flow limiting shell are fixedly connected with a blocking ring plate.

Preferably, no. two screening devices include the screening shell, the top fixed connection of screening shell is in the bottom of current-limiting shell, the bottom fixed connection of screening shell is at detection device's top, the inner wall of screening shell rotates and is connected with the turn bar, the surface of turn bar is fixedly connected with pressure components and spoiler respectively.

Preferably, the number of the pressure components is a plurality, the pressure components are arranged in a circumferential array mode, the central part formed by the pressure components is fixedly connected with an expansion ball, and the surface of the expansion ball is fixedly connected with a contraction rope.

Preferably, one end of the contraction rope, which is far away from the expansion ball, is fixedly connected with a furling scale, two sides of the furling scale are slidably connected to the inner wall of the pressure assembly, and the furling scales are arranged in an overlapped progressive mode.

The invention provides a sampling screen filter for hyperspectral water quality detection. The method has the following beneficial effects:

1. this high spectrum water quality testing is with sample sieve filter, through the downthehole water that need detect of pouring into that sets up to the top cap surface, often have some water to sputter or overflow from downthehole, these overflow and come water and will follow the annular ring and get into to through the hollow crown plate of connecting in the annular ring bottom, at last from the back flow get back to sieve filter again and strain in the device, in order to reach the effect of ensureing to detect the quality of water accuracy

2. The sampling screen filter for hyperspectral water quality detection forms spiral flow along the auger blade when water flow normally flows into the screening die sleeve, the water flow simultaneously contacts the inner wall of the screening die sleeve to screen and adhere the adhering column to impurities in water, wherein the auger blade is used for increasing the contact area between the water flow and the screening die sleeve so as to increase the screening effect on water quality, and when the water flow is too large, the auger blade is extruded by the water to form a compression state along the adhering column, so that the connecting plate fixed at the lower half section of the auger blade can drive the circulation base to move downwards, the circulation base and the upper surface of the hole plate form a folding trend so as to reduce the water flow flowing out from the screening die sleeve, increase rivers and sieve filter die sleeve and adhesion post between contact time, wherein fix the effect that not only plays absorption aquatic impurity at the absorption sponge of trompil board upper surface, it lets rivers pass through to leave a space when circulation base and trompil board fold still to play, prevent that rivers from blockking up accumulational effect, when rivers overload, the circulation base will extrude the absorption sponge, make absorption sponge shrink and extrude the trompil board, at this moment, the trompil board will be along the outer wall of sieve filter die sleeve and the inner wall downstream of pressure relief groove, make inside water of sieve filter die sleeve partly flow into in the pressure relief inslot and flow into the pressure relief inslot from the pressure relief hole that the trompil board surface was seted up from the upper surface of trompil board, in order to reach the effect of pressure relief, wherein keep confined always between trompil board and sieve filter die sleeve and the pressure relief groove.

3. This high spectrum water quality testing is with sample sieve filter, through when rivers normally flow in inside the inner sliding sleeve, rivers can pour into from the standpipe entry, then flow out from the export and get into the slip shell inside again, wherein be sealed between movable plate and the inner sliding sleeve, get into in the next device afterwards, when rivers are too big or rivers are poured into the speed and are greater than the speed that flows out from the standpipe, movable plate will move down along the slide bar, at last by propping on the check ring, at this moment can produce the space between movable plate and the inner sliding sleeve, make rivers pass through, so as to reach the effect of pressure release, movable plate and check ring will drive the inner sliding sleeve and take place the downward removal at the inner wall of slip shell when rivers overload, slide when the inner sliding sleeve slides to the bottom of slip shell and will block, then the inner sliding sleeve will drive the slip shell and take place the downward removal, make the extrusion board of fixing in the bottom of slip shell constantly break through the blockking of ring board take place the downward removal, so as to reach the effect that the increase space and let more rivers pass through, wherein the height of inner sliding sleeve is greater than the slip shell, in addition between slip shell and the confined state always be in the restriction shell.

4. This high spectrum water quality testing sieves filter with sample, through when a small amount of rivers flow into sieve filter shell inside, rivers will pile up on forming the pressure assembly between closed area, and the spoiler is also confined simultaneously to reach dual seal and increase and sieve the effect of straining the time to rivers. When water flow is too large or excessive water is accumulated, the pressure assembly can rotate inwards in a shrinking mode by taking the turning rod as a circle center, meanwhile, the spoiler can expand outwards by taking the turning rod as the circle center to release the sealing effect, in addition, the pressure assembly can extrude the expansion ball, so that the expansion ball can continuously shrink and pull the contraction rope, at the moment, the furling scales fixed at the other end of the contraction rope can move along the inner wall of the pressure assembly in the direction of the expansion ball, the furling scales connected with the contraction rope are the scales which are farthest away from the expansion ball, and the furling scales are connected in a stacking mode, so the furling scales can be pulled by the contraction rope to form a whole block, and the water flow circulation effect is achieved.

Drawings

FIG. 1 is a schematic structural view of a sampling screen filter for hyperspectral water quality detection according to the invention;

FIG. 2 is a schematic sectional view of the present invention;

FIG. 3 is a schematic view of a reflow apparatus according to the present invention;

FIG. 4 is a schematic structural view of a first screening device according to the present invention;

FIG. 5 is a schematic view of a screen filter according to the present invention;

FIG. 6 is a schematic view of the pressure relief device according to the present invention;

FIG. 7 is a schematic view of a current limiting device according to the present invention;

FIG. 8 is a schematic view of a full-section view of a flow limiting device according to the present invention;

FIG. 9 is a schematic structural view of a second screening device according to the present invention;

FIG. 10 is a schematic view of the internal structure of the second screening device of the present invention;

FIG. 11 is a schematic view of a full-section structure of a second screening device of the present invention.

In the figure: 1. a top cover; 2. a housing; 3. a reflux unit; 4. a first screening device; 5. a current limiting device; 6. a second screening device; 7. a detection device; 8. a collection device; 31. an annular hole; 32. a hollow ring plate; 33. a return pipe; 41. a screen filter; 42. a pressure relief device; 411. screening and filtering a die sleeve; 412. a connecting rod; 413. adhering the column; 414. a screw blade; 415. a connecting plate; 416. a flow-through base; 421. a pressure relief vent; 422. a perforated plate; 423. a pressure relief groove; 424. adsorbing a sponge; 51. an inner sliding sleeve; 52. a current limiting housing; 53. a movable plate; 54. a vertical tube; 55. a barrier ring plate; 56. a pressing plate; 57. a check ring; 58. a slide bar; 59. a sliding shell; 61. screening the shell; 62. a pressure assembly; 63. collecting scales; 64. retracting the cord; 65. an expansion ball; 66. a bending rod; 67. a spoiler.

Detailed Description

The invention is described in further detail below with reference to the drawings and the detailed description. The embodiments of the present invention have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the invention in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiment was chosen and described in order to best explain the principles of the invention and the practical application, and to enable others of ordinary skill in the art to understand the invention for various embodiments with various modifications as are suited to the particular use contemplated.

As shown in fig. 1 to 11, the present invention provides a technical solution: a sampling screen filter for hyperspectral water quality detection comprises a top cover 1, a shell 2, a backflow device 3, a first screening device 4, a flow limiting device 5, a second screening device 6, a detection device 7 and a collection device 8, wherein the bottom of the top cover 1 is fixedly connected to the top of the backflow device 3, the surface of the backflow device 3 is inserted into the first screening device 4, the top of the first screening device 4 is fixedly connected to the bottom of a through hole formed in the surface of the top shell 1, the top of the shell 2 is fixedly connected to the bottom of the top shell 1, the bottom of the first screening device 4 is fixedly connected to the top of the flow limiting device 5, the bottom of the flow limiting device 5 is fixedly connected to the top of the second screening device 6, the bottom of the second screening device 6 is fixedly connected to the top of the detection device 7, the bottom of the detection device 7 is fixedly connected to the top of the collection device 8, and the outer surface of the collection device 8 is fixedly connected to the inner wall of the shell 2;

the backflow device 3 comprises a hollow ring plate 32, the surface of the top cover 1 is provided with a ring-shaped hole 31, the bottom of the top cover 1 is fixedly connected to the top of the hollow ring plate 32, the top of the hollow ring plate 32 faces the ring-shaped hole 31, one end of the hollow ring plate 32, which is far away from the top cover 1, is fixedly connected with a backflow pipe 33, and the surface of the backflow pipe 33 is inserted into the first screening device 4; by injecting water to be detected into the holes formed on the surface of the top cover 1, part of water is often splashed or overflowed from the holes, and the overflowed water enters from the annular hole 31, passes through the hollow annular plate 32 connected to the bottom of the annular hole 31 and finally returns to the first screening device 4 from the return pipe 33 to be screened and filtered

Device 4 is strained to first sieve includes sieve filter 41, the bottom fixedly connected with cover of sieve filter 41 is equipped with pressure relief device 42, sieve filter 41 strains die sleeve 411 including the sieve, the top fixed connection that the die sleeve 411 was strained to the sieve is in the bottom of top cap 1, the first half fixedly connected with connecting rod 412 of die sleeve 411 inner wall is strained to the sieve, the one end fixedly connected with that the die sleeve 411 was strained to the sieve is kept away from to connecting rod 412 glues post 413, the surface sliding connection that glues post 413 has auger blade 414, one side sliding connection that auger blade 414 kept away from gluing post 413 is on the inner wall that die sleeve 411 was strained to the sieve, auger blade 414 second half's outside fixedly connected with connecting plate 415, the bottom fixedly connected with circulation base 416 of connecting plate 415.

Pressure relief device 42 includes pressure relief groove 423, pressure relief groove 423's bottom fixed connection is at current limiting device 5's top, pressure relief groove 423's inner wall sliding connection has trompil board 422, the inner wall sliding connection of trompil board 422 first half section is in the outside of screening die sleeve 411 lower extreme, pressure release hole 421 has been seted up on the surface of trompil board 422 department of buckling, trompil board 422's last fixed surface is connected with adsorbs sponge 424. When water flow normally flows into the inside of the screening die sleeve 411, water flows spirally along the auger blade 414, the water flow simultaneously contacts the inner wall of the screening die sleeve 411 to screen and adhere the adhering column 413 to impurities in the water, when the water flow is too large, the water presses the auger blade 414 to enable the auger blade 414 to form a compression state along the adhering column 413, so that the connecting plate 415 fixed on the lower half section of the auger blade 414 drives the circulating base 416 to move downwards, the circulating base 416 and the upper surface of the opening plate 422 form a closed trend, when the water flow is overloaded, the circulating base 416 presses the adsorbing sponge 424 to enable the adsorbing sponge 424 to contract and press the opening plate 422, at the moment, the opening plate 422 moves downwards along the outer wall of the screening die sleeve 411 and the inner wall of the pressure relief groove 423, and a part of the water in the screening die sleeve 411 flows into the pressure relief groove 423 from the upper surface of the opening plate 422 and flows into the pressure relief groove 423 from the pressure relief hole 421 formed on the surface of the opening plate 422, wherein the water flow between the screening die sleeve 422 and the pressure relief groove 423 is kept closed.

The flow limiting device 5 comprises an inner sliding sleeve 51, the top of the inner sliding sleeve 51 is fixedly connected to the bottom of the pressure relief groove 423, the outer surface of the inner sliding sleeve 51 is slidably connected with a sliding shell 59, the outer surface of the sliding shell 59 is slidably connected with a flow limiting shell 52, the inner wall of the inner sliding sleeve 51 is fixedly connected with a sliding rod 58, the bottom of the sliding rod 58 is fixedly connected with a check baffle ring 57, the surface of the sliding rod 58 is slidably connected with a movable plate 53, the surface of the movable plate 53 is sleeved with a vertical pipe 54, the vertical pipe 54 penetrates through the surface of the movable plate 53 and extends to the outside, the bottom of the sliding shell 59 is fixedly connected with an extrusion plate 56, and the upper side and the lower side of the inner wall of the flow limiting shell 52 are fixedly connected with a blocking ring plate 55. When water normally flows into the inner sliding sleeve 51, the water is injected from the inlet of the vertical pipe 54 and then flows out from the outlet and enters the inside of the sliding shell 59, wherein the movable plate 53 and the inner sliding sleeve 51 are sealed, and then enters the next device, when the water is too large or the water injection speed is higher than the outflow speed from the vertical pipe 54, the movable plate 53 moves downwards along the sliding rod 58 and finally abuts against the check ring 57, a gap is generated between the movable plate 53 and the inner sliding sleeve 51, so that the water flows through, when the water flow is overloaded, the movable plate 53 and the check ring 57 carry the inner sliding sleeve 51 to move downwards on the inner wall of the sliding shell 59, when the inner sliding sleeve 51 slides to the lowest end of the sliding shell 59, and then the inner sliding sleeve 51 drives the sliding shell 59 to move downwards, so that the extrusion plate 56 fixed at the bottom of the sliding shell 59 continuously breaks through the block of the block ring plate 55 to move downwards.

The second screening device 6 comprises a screening shell 61, the top of the screening shell 61 is fixedly connected to the bottom of the flow limiting shell 52, the bottom of the screening shell 61 is fixedly connected to the top of the detection device 7, the inner wall of the screening shell 61 is rotatably connected with a bending rod 66, the surface of the bending rod 66 is respectively fixedly connected with a plurality of pressure assemblies 62 and a spoiler 67, the pressure assemblies 62 are arranged in a circumferential array, the central part formed by the pressure assemblies 62 is fixedly connected with an expansion ball 65, the surface of the expansion ball 65 is fixedly connected with a contraction rope 64, one end of the contraction rope 64 far away from the expansion ball 65 is fixedly connected with a furling scale 63, two sides of the furling scale 63 are slidably connected to the inner wall of the pressure assemblies 62, and the furling scales 63 are arranged in an overlapped progressive manner.

When the device is used, water to be detected is injected into the holes formed in the surface of the top cover 1, and part of water is sputtered or overflows from the holes, and the overflowed water enters from the annular hole 31 and returns to the first screening device 4 again through the hollow annular plate 32 connected to the bottom of the annular hole 31 to be screened and filtered, so that the effect of ensuring the accuracy of the detected water quality is achieved. When a small amount of water flows into the interior of the screen casing 61, the water flow accumulates on the pressure assembly 62 forming an enclosed area, and the flow blocking plate 67 is also enclosed, thereby achieving a double closure and increasing the screening time for the water flow. When the water flow is too large or the water is too much accumulated, the pressure assembly 62 rotates to contract inwards around the turn bar 66, the spoiler 67 expands outwards around the turn bar 66 to release the closing effect, the pressure assembly 62 presses the expansion ball 65, the expansion ball 65 contracts continuously and pulls the contraction rope 64, the furling scales 63 fixed at the other end of the contraction rope 64 move along the inner wall of the pressure assembly 62 in the direction of the expansion ball 65, the furling scales 63 connected with the contraction rope 64 are the ones farthest away from the expansion ball 65, and the furling scales 63 are connected in an overlapping manner by the furling rope 64, so that the furling scales 63 are pulled by the contraction rope 64 to form a whole block

When water flow normally flows into the sieving and filtering die sleeve 411, water can form spiral flow along the auger blade 414, the water flow can simultaneously contact the inner wall of the sieving and filtering die sleeve 411 for sieving and filtering and adhesion of the adhesion column 413 to impurities in the water, wherein the auger blade 414 is used for increasing the contact area between the water flow and the sieving and filtering die sleeve 411 so as to increase the sieving and filtering effect on water quality, when the water flow is too large, the auger blade 414 can be extruded by the water, so that the auger blade 414 forms a compression state along the adhesion column 413, therefore, the connecting plate 415 fixed at the lower half section of the auger blade 414 can drive the flow base 416 to move downwards, so that the flow base 416 and the upper surface of the opening plate 422 form a folding trend, thereby reducing the water flow flowing out from the sieving and filtering die sleeve 411 and increasing the contact time between the water flow and the sieving and filtration die sleeve 411 and the adhesion column 413, the adsorption sponge 424 fixed on the upper surface of the perforated plate 422 not only has the function of adsorbing impurities in water, but also has the function of leaving a wire gap for water to pass when the circulation base 416 and the perforated plate 422 are folded, so as to prevent water flow from blocking and accumulating, when the water flow is overloaded, the circulation base 416 can extrude the adsorption sponge 424, so that the adsorption sponge 424 shrinks and extrudes the perforated plate 422, at this time, the perforated plate 422 can move downwards along the outer wall of the screening mold sleeve 411 and the inner wall of the pressure relief groove 423, so that a part of water in the screening mold sleeve 411 flows into the pressure relief groove 423 from the upper surface of the perforated plate 422 and flows into the pressure relief groove 423 from the pressure relief holes 421 formed in the surface of the perforated plate 422, so as to achieve the pressure relief function, wherein the spaces among the perforated plate 422, the screening mold sleeve 411 and the pressure relief groove 423 are kept closed all the time.

When water normally flows into the inner sliding sleeve 51, the water flows in from the inlet of the vertical pipe 54, then flows out from the outlet and enters the inside of the sliding shell 59, wherein the movable plate 53 and the inner sliding sleeve 51 are sealed, and then enters the next device, when the water flow is too large or the water flow injection speed is higher than the water flow speed from the vertical pipe 54, the movable plate 53 moves downwards along the sliding rod 58 and finally is abutted against the blocking ring 57, then a gap is formed between the movable plate 53 and the inner sliding sleeve 51, so that the water flow passes through, so as to achieve the pressure relief effect, when the water flow is overloaded, the movable plate 53 and the blocking ring 57 carry the inner sliding sleeve 51 to move downwards on the inner wall of the sliding shell 59, when the inner sliding sleeve 51 slides to the lowest end of the sliding shell 59, then the inner sliding sleeve 51 drives the sliding shell 59 to move downwards, so that the extrusion plate 56 fixed at the bottom of the sliding shell 59 continuously breaks through the blocking ring 55 to achieve the effect of increasing the gap for allowing more water flow to pass, wherein the height of the inner sliding sleeve 51 is higher than the sliding shell 59, and the other sliding shell 52 is in a closed state of limiting flow between the sliding shell 59.

When a small amount of water flows into the interior of the screen casing 61, the water accumulates on the pressure assembly 62 forming an enclosed area, and the baffle 67 is also closed, thereby achieving a double closure and increasing the screening time for the water flow. When the water flow is too large or the water is too much accumulated, the pressure assembly 62 rotates by contracting inwards around the bent rod 66, the spoiler 67 expands outwards around the bent rod 66 to release the closing effect, the pressure assembly 62 presses the expansion ball 65, so that the expansion ball 65 continuously contracts and pulls the contraction rope 64, the furling scale 63 fixed at the other end of the contraction rope 64 moves along the inner wall of the pressure assembly 62 in the direction of the expansion ball 65, wherein the furling scale 63 connected with the contraction rope 64 is the farthest piece from the expansion ball 65, and because the furling scales 63 are connected in a stacked manner, the furling scale 63 is pulled by the contraction rope 64 to form a whole piece to achieve the water flow circulation effect.

It is to be understood that the described embodiments are merely a few embodiments of the invention, and not all embodiments. All other embodiments, which can be derived by one of ordinary skill in this and related arts based on the embodiments of the present invention without creative efforts, shall fall within the protection scope of the present invention. Structures, devices, and methods of operation not specifically described or illustrated herein are generally practiced in the art without specific recitation or limitation.

Claims

1. The utility model provides a hyperspectral water quality testing is with sample sieve filter, includes top cap (1), shell (2), reflux unit (3), a sieve and strains device (4), current limiting device (5), no. two sieves and strains device (6), detection device (7) and collection device (8), its characterized in that: the bottom of the top cover (1) is fixedly connected to the top of the backflow device (3), the surface of the backflow device (3) is inserted into the first screening device (4), the top of the first screening device (4) is fixedly connected to the bottom of a through hole formed in the surface of the top shell (1), the top of the shell (2) is fixedly connected to the bottom of the top shell (1), the bottom of the first screening device (4) is fixedly connected to the top of the flow limiting device (5), the bottom of the flow limiting device (5) is fixedly connected to the top of the second screening device (6), the bottom of the second screening device (6) is fixedly connected to the top of the detection device (7), the bottom of the detection device (7) is fixedly connected to the top of the collection device (8), and the outer surface of the collection device (8) is fixedly connected to the inner wall of the shell (2);

the backflow device (3) comprises a hollow ring plate (32), a ring-shaped hole (31) is formed in the surface of the top cover (1), the bottom of the top cover (1) is fixedly connected to the top of the hollow ring plate (32), the top of the hollow ring plate (32) faces the ring-shaped hole (31), a backflow pipe (33) is fixedly connected to one end, far away from the top cover (1), of the hollow ring plate (32), and the surface of the backflow pipe (33) is inserted into the first screening device (4);

device (4) are strained to a sieve includes sieve filter (41), the bottom cover of sieve filter (41) is equipped with pressure relief ware (42), sieve filter (41) are including sieve filter die sleeve (411), the top fixed connection of sieve filter die sleeve (411) is in the bottom of top cap (1), the first half fixedly connected with connecting rod (412) of sieve filter die sleeve (411) inner wall, the one end fixedly connected with who sieves filter die sleeve (411) is kept away from in connecting rod (412) adheres post (413), the surface sliding connection who adheres post (413) has auger blade (414), one side sliding connection who adheres post (413) is kept away from in auger blade (414) is on the inner wall of sieve filter die sleeve (411), outside fixedly connected with connecting plate (415) of auger blade (414) second half, the bottom fixedly connected with circulation base (416) of connecting plate (415).

2. The hyperspectral water quality detection sampling screen filter as recited in claim 1, wherein: pressure release ware (42) are including pressure release groove (423), the bottom fixed connection of pressure release groove (423) is at the top of current limiting device (5), the inner wall sliding connection who releases pressure groove (423) has trompil board (422), the inner wall sliding connection of trompil board (422) first half section is in the outside of screening die sleeve (411) lower extreme, pressure release hole (421) have been seted up on the surface of trompil board (422) department of buckling, the last fixed surface of trompil board (422) is connected with adsorbs sponge (424).

3. The hyperspectral water quality detection sampling screen filter as recited in claim 1, wherein: the flow limiting device (5) comprises an inner sliding sleeve (51), the top of the inner sliding sleeve (51) is fixedly connected to the bottom of the pressure relief groove (423), the outer surface of the inner sliding sleeve (51) is slidably connected with a sliding shell (59), and the outer surface of the sliding shell (59) is slidably connected with a flow limiting shell (52).

4. The hyperspectral water quality detection sampling screen filter as recited in claim 3 is characterized in that: the inner wall of the inner sliding sleeve (51) is fixedly connected with a sliding rod (58), the bottom of the sliding rod (58) is fixedly connected with a grid baffle ring (57), the surface of the sliding rod (58) is connected with a movable plate (53) in a sliding mode, the surface of the movable plate (53) is sleeved with a vertical pipe (54), and the vertical pipe (54) penetrates through the surface of the movable plate (53) and extends to the outside.

5. The hyperspectral water quality detection sampling screen filter according to claim 3, which is characterized in that: the bottom of the sliding shell (59) is fixedly connected with an extrusion plate (56), and the upper side and the lower side of the inner wall of the flow limiting shell (52) are fixedly connected with a blocking ring plate (55).

6. The hyperspectral water quality detection sampling screen filter as recited in claim 1, wherein: no. two screening devices (6) are including screening shell (61), the top fixed connection of screening shell (61) is in the bottom of current-limiting shell (52), the bottom fixed connection of screening shell (61) is at the top of detection device (7), the inner wall of screening shell (61) rotates and is connected with curved pole (66), the surface difference fixedly connected with pressure components (62) and spoiler (67) of curved pole (66).

7. The hyperspectral water quality detection sampling screen filter according to claim 6, which is characterized in that: the number of the pressure components (62) is a plurality, the pressure components are arranged in a circumferential array mode, an expansion ball (65) is fixedly connected to the center portion formed by the pressure components (62), and a contraction rope (64) is fixedly connected to the surface of the expansion ball (65).

8. The hyperspectral water quality detection sampling screen filter according to claim 7 is characterized in that: one end of the contraction rope (64) far away from the expansion ball (65) is fixedly connected with a furling scale (63), two sides of the furling scale (63) are connected to the inner wall of the pressure assembly (62) in a sliding mode, and the furling scales (63) are arranged in an overlapped progressive mode.