CN110935205A - Multi-stage sedimentation rake-free concentration device comprising laminar flow-guiding sedimentation sieve - Google Patents

Abstract

The invention relates to a multistage sedimentation rake-free concentration device comprising a laminar flow guiding sedimentation screen, which comprises a central tank body, wherein a guiding sedimentation area is arranged outside the central tank body, the guiding sedimentation area comprises the laminar flow guiding sedimentation screen and a magnetism gathering sprayer, the laminar flow guiding sedimentation screen comprises a plurality of third guiding sedimentation sub groups which are sequentially arranged downwards along the outer wall of the central tank body, in two adjacent sedimentation tanks, the lower sedimentation tank obtains slime water flowing out from the previous sedimentation tank, each third guiding sedimentation sub group comprises a sedimentation tank, a bottom plate of each sedimentation tank is provided with a third underflow discharge port for discharging settled fine slime, and the completely settled water is output from a third overflow discharge pipe at the output end of the third underflow sedimentation sub group at the lowest position. In the invention, the diversion sedimentation area uses a laminar flow diversion sedimentation screen to sequentially pass through all the third diversion sedimentation subgroups, thereby realizing progressive sedimentation, discharging fine coal slime and settled water from different pipes and realizing concentration.

Description

Multi-stage sedimentation rake-free concentration device comprising laminar flow-guiding sedimentation sieve

Technical Field

The invention relates to the field of slime water treatment, in particular to a multistage sedimentation rake-free concentration device comprising a laminar flow-reducing diversion sedimentation screen.

Background

The treatment of coal slurry water in the washing and selecting process of coal is used as the ending link of the washing and selecting process, which is the key of the effective collection and utilization of coal slurry and the closed-circuit circulation of washing and selecting water, and the concentration device is widely used as the carrier and the key equipment of the treatment of coal slurry water, and has important significance for the closed-circuit circulation of washing and selecting water, the full utilization of underflow concentrate and environmental protection.

Along with the integration and large-scale of coal washing plants, the treatment capacity is greatly improved, the output of slime water and the content of fine mud in the slime water are also greatly increased, so that the diameter of a concentration device is continuously increased in the application process, the existing equipment has a specification reaching 45m or more, and the fine mud is more refined and the treatment capacity is increased, so that the settling time period is short, the settling effect is poor, the fine mud in washing circulating water cannot be effectively separated, the coal washing quality is seriously influenced, and therefore, two-stage concentration or even three-stage concentration is added for further purifying the washing circulating water in many coal washing plants, a large amount of land is occupied, coal-carrying foam which is not completely recovered in a flotation stage is still remained in the slime water, the waste of fine coal is caused, and the economic loss is caused.

Disclosure of Invention

In order to fully utilize the multistage sedimentation technology to realize the multistage concentration combination on the structure of the thickener, the defoaming technology is utilized to realize the recovery and utilization of clean coal on the residual mineralized foam, so that the occupied area is greatly reduced, the clean coal recovery is increased, the multistage diversified utilization of the coal slime is realized, the economic income is increased, and the waste is reduced. Therefore, the invention provides a multi-stage sedimentation rake-free concentration device comprising a layer-falling diversion sedimentation screen.

In order to achieve the purpose, the invention adopts the following technical scheme:

the utility model provides a do not have harrow enrichment facility including multistage settlement of laminar flow reduction water conservancy diversion sieve subsides, includes central cell body, the central cell body outside is provided with the water conservancy diversion settlement district, the water conservancy diversion settlement district is including laminar flow reduction water conservancy diversion sieve subsides and gather the magnetism spray thrower, laminar flow reduction water conservancy diversion sieve subsides includes a plurality of third water conservancy diversion settlement subgroups that set gradually downwards along central cell body outer wall, and in two adjacent subsiders, the below subsider obtains the coal slime water that last subsider flowed, and every third water conservancy diversion subsides the subgroup and includes the subsider, is provided with the third underflow bin outlet with the thin coal slime of subsiding on the bottom plate of subsider, and the water after completely subsiding subsides the third overflow blow-off pipe output of the output end department of subgroup from the third rivers of below.

The invention has the advantages that:

(1) in the invention, the diversion sedimentation area uses a laminar flow diversion sedimentation screen to sequentially pass through all the third diversion sedimentation subgroups, thereby realizing progressive sedimentation, discharging fine coal slime and settled water from different pipes and realizing concentration.

(2) This device realizes that traditional multistage concentrated pond is structural unites two into one, the area in traditional multistage concentrated pond that has significantly reduced.

(3) The device arranges the central aggregate region in the central tank body in the clean coal collecting assembly, and the foam is collected to the center through the first guide plate, and the fluid is settled step by step along the radial direction, and the overflow water is collected automatically, so that the unpowered self-flow of the fluid is realized.

(4) The separation of coarse coal slime products and fine coal slime products is realized, the coarse coal slime products can be used as the coal blending of middling coal products due to high coal content, the economic income is increased, the waste is reduced, the fine coal slime products are accumulated and discharged in a centralized manner, the pollution is reduced, the more sufficient separation of the fine coal slime and water is realized, and the washing process deterioration phenomenon caused by circulating water is greatly improved.

(5) Whether the fine mud can settle in the thickener mainly depends on the movement distance of fine particles in the vertical direction, and the arrangement of high and low guide plates in the diversion settling sieve can ensure that the slime water obtains sufficient settling time in a limited space, thereby realizing the full settling of the fine mud.

(6) The setting of bubble breaker can realize the desorption of concentrate on the residual mineralize mineralization bubble through the mode of pulsation hammering, and the efflux water still can realize washing and collecting of attaches wall concentrate simultaneously.

(7) Gather magnetic shower's setting and can use magnetic particle as the kind of magnetism, strengthen the depending on of flocculating agent to the adhesion of thin mud and flocculating agent is accelerated, the settlement with higher speed of realizing thin mud, the abundant separation of further realization mud and water.

(8) The vortex-shaped first guide plate can reduce the turbulence degree of jet feeding in the central tank body, optimize the environment of coal slime sedimentation and facilitate sedimentation; meanwhile, the traditional stirring rake is not needed, the rake pressing phenomenon is thoroughly solved, and the continuous and stable work of the thickener is ensured.

(9) The setting of pan feeding subassembly is through drawing the interpolation that penetrates the effect and realize flocculating agent, expands suddenly through the fluid simultaneously and contracts suddenly, leads to the change of pressure differential, leads to appearing the turbulent aggravation phenomenon to realize the intensive mixing of flocculating agent and ore pulp.

Drawings

FIG. 1 is a schematic view of the direction of flow of coal slime water in the present invention.

Fig. 2 is a structural diagram of the whole device when the diversion settling area is the first scheme.

Fig. 3 is a structural diagram of the whole device when the diversion settling area is the second scheme.

Fig. 4 is a structural diagram of the whole apparatus when the guide settling zone is the third scheme.

FIG. 5 is a structural diagram of a clean coal collection assembly with a diversion settling zone as the first option.

Fig. 6 is a schematic structural diagram of a foam-removing area when the diversion sedimentation area is the first scheme.

Fig. 7 is a structural diagram of a diversion sedimentation zone in the first scheme.

Fig. 8 is a structural diagram of a foam extinguishing area when the diversion sedimentation area is the second scheme and the third scheme.

Fig. 9-10 are structural diagrams of a diversion settling zone in a second embodiment.

Fig. 11 is a structural view of a guide settling zone in the third embodiment.

Fig. 12 is a structural view of a first distributing device, a second distributing device and a third distributing device.

Fig. 13 is a top view of a first baffle in a central trough.

The notations in the figures have the following meanings:

11-feeding distribution groove 12-main feeding pipe 13-reducing pipe 14-medicament injection pipe

21-central groove body 22-jet flow feeding pipe 23-first guide plate

24-first discharge hole 25-central support column 26-horizontal support rod 27-overflow groove

31-central collecting space

320-lower board 321-side board 322-upper board 323-lower board

324-sudden shrinkage and sudden expansion spoiler 325-spoiler settlement plate

331-first underflow discharge pipe 332-first discharge valve

341-impact tube 342-grooved roller 343-hammering foam-removing plate 344-hammering rod

345-diversion bent plate 346-reciprocating spring 347-clean coal collecting groove 348-support

351-first magnetism-gathering injection pipe 352-first magnetic powder feeding pipe 353-first distributor

361-second magnetic gathering injection pipe 362-second magnetic powder feeding pipe 363-second distributing device

371-ring groove 3711-second spoiler baffle 3712-second underflow discharge outlet

372-second inclined plate diversion and discharge pipe 373-second underflow discharge pipe 374-second overflow discharge pipe

381-third magnetic injection pipe 382-third magnetic powder feeding pipe 383-third distributing device

391-settling tank 3911-third baffle

392-third inclined plate flow guide and discharge pipe 393-third underflow discharge pipe 394-third overflow discharge pipe

395-connecting pipe

Detailed Description

A multi-stage sedimentation rake-free concentration device comprising a layer-falling diversion sedimentation screen comprises a feeding assembly, a diversion assembly and a clean coal collection assembly. The water conservancy diversion subassembly includes that the upper end is central cell body 21 of cylinder portion, lower extreme for funnel portion, central cell body 21 is the cavity structure, the pan feeding subassembly sets up in the cavity top of central cell body 21, the lower tip of central cell body 21 is provided with first discharge gate 24. The coarse slime is gradually settled above the first discharge port 24 of the central groove body 21 and is settled to reach a certain settlement amount, the coarse slime is discharged through the first discharge port 24, and materials discharged from the first discharge port 24 are collected and used for blending middlings or used as building materials, so that the economic income is increased.

As shown in fig. 1, the material and the chemical enter the diversion assembly from the feeding assembly, that is, the direction a in fig. 1, and diffuse outward from the middle, and then converge to the middle through the diversion assembly, as the direction b in the figure, the arrangement of the direction a and the direction b increases the flow paths of the material and the chemical, thereby increasing the reaction time, and further enhancing the reaction effect. The clean coal collecting assembly collects residual mineralized bubbles above the center of the central groove body, the fine coal slime moves towards the edge of the central groove body according to the direction d, defoaming is achieved in the process, and the sedimentation area is arranged behind the defoaming area and can separate water and the settled fine coal slime through sedimentation.

The components are described in detail below.

1. Feeding assembly

As shown in fig. 2-4, the feeding assembly includes a feeding distribution chute 11, a main feeding pipe 12, a reducer pipe 13, and a chemical injection pipe 14. The plurality of reducer pipes 13 are uniformly distributed between the side walls of the feed distribution chute 11 and the central chute body 21.

The material is input into the feeding distribution groove 11 through the main feeding pipe 12, a plurality of reducing pipes 13 are annularly arrayed between the inner lower part of the feeding distribution groove 11 and the inner side wall of the cylindrical part of the central groove body 21, and in the scheme, the reducing pipes 13 are composed of round balls and round pipes to form calabash-shaped pipes with sudden expansion and sudden contraction alternation.

The medicament draws penetrates pipe 14 equipartition in the sudden shrinkage department of reducing pipe 13 to be linked together with the pipe of sudden shrinkage department, because the velocity of flow of sudden shrinkage department can increase suddenly, draw the handing-over department formation negative pressure of pipe 14 and reducing pipe 13 at the medicament, consequently can draw the flocculating agent of penetrating in the pipe 14 to the medicament and play fine suction effect, at the sudden expansion department pressure increase, the velocity of flow slows down, turbulent intensity increases at this moment, flocculating agent and slime water obtain intensive mixing.

The opening degree of the inlet of the medicament injection pipe 14 can be controlled by a superior valve to regulate and control the medicament inhalation amount. The materials and the medicament are mixed by the injection of the reducer pipe 13.

Wherein, the bottom of the feeding distribution groove 11 is provided with a central support column 25, the central support column 25 is provided with a horizontal support rod 26, and the horizontal support rod 26 supports the feeding assembly through a component outside the device.

In the scheme, the reducer pipe 13 serves as an output end of the feeding assembly and distributes the slime water outwards from the feeding distribution groove 11.

2. Flow guide assembly

As shown in fig. 2-4, the flow guide assembly includes a jet feeding pipe 22 and a first flow guide plate 23, an input end of the jet feeding pipe 22 is connected to an output end of the feeding assembly, one end of the first flow guide plate 23 is fixed on an inner side wall of the cylindrical portion of the central tank 21, and the other end extends to the middle of the central tank 21. In the scheme, each jet flow feeding pipe 22 is connected with the output end of the corresponding reducer pipe 13, and a corresponding first guide plate 23 is arranged below the outlet of each jet flow feeding pipe 22. The mixed fluid is injected to the first guide plate 23 of the central groove body 21 through the jet flow feeding pipe 22, the slime water is uniformly and orderly distributed in the central groove body 21 to be settled under the guide effect of the first guide plate 23, the material and the medicament are mixed and reacted in the area and the central groove body 21, the coarse slime is gradually settled to the deep cone of the central groove body 21 to be settled, and a certain deposition amount is discharged through the first discharge hole 24. In this embodiment, as shown in fig. 13, the first baffles 23 are distributed in a vortex shape, and 6 jet feeding pipes 22 are arranged in an annular array. The spiral structure is also used for increasing the flow path of materials and medicaments.

3. Clean coal collecting assembly

Clean coal collection assembly still includes the subsidence district that corresponds with the district that disappears including the central district 31 that gathers materials, a plurality of bubble districts that disappear that encircle support column 25, a plurality of bubble districts annular array gather materials between district 31 and cylinder portion inside wall in the center, first guide plate 23 in the water conservancy diversion subassembly and efflux pan feeding pipe 22's output all are located the below in the district that disappears.

3.1, central collecting area 31

As shown in fig. 2-6 and 8, the central material collecting area 31 is a circular groove structure with an upward opening, the circular groove structure is sleeved on the supporting column 25, and after the material reacts with the chemical, the fine coal slurry generates bubbles in the reaction of the chemical, and carries clean coal to move upward to the central material collecting area 31.

3.2 bubble eliminating zone

As shown in fig. 2-6 and 8, the bubble-removing area includes a first diversion sedimentation screen, and a plurality of bubble-removing devices located at a set position above the first diversion sedimentation screen, and the bubble-removing devices are sequentially arranged along the fluid flowing direction, so as to improve the bubble-removing effect.

3.2.1 first diversion sedimentation screen

The first diversion sedimentation screen comprises side plates 321 on two sides, a first diversion area is enclosed by a lower plate body 320, the lower plate body 320 is communicated with a first underflow discharge pipe 331 below the lower plate body through a first discharge valve 332, and thus, clean coal deposited at the bottom can be recovered. One end of the first underflow discharge pipe 331 is fixed on the support column 25 in a sealing manner, and the other end extends out of the central trough body 21. The first material discharge valve 332 is opened at a fixed time, so that the material with clean coal deposited on the lower plate body 320 can be discharged. The upper end of the side plate 321 is higher than the outer edge of the central material-collecting area 31, so that the material overflowing from the central material-collecting area 31 to the first guiding area can not directly overflow and needs to be treated by the clean coal collecting assembly. The height of the upper end of the high plate 322 of the first flow guiding area is gradually reduced along the radial direction of the cylindrical part.

Preferably, the first flow guiding region is alternately provided with high plates 322 and low plates 323 at intervals along the fluid flowing direction, and the high plates 322 and the low plates 323 are staggered up and down and are fixedly connected between the two side plates 321 at intervals. Fluid flows through the lower end of the high-level plate 322 and the upper end of the low-level plate 323, and the sedimentation rate of the fine coal slurry fluid is increased. The left side of the first discharge valve 332 at each lower plate 320 is a high plate 322, and the right side is a low plate 323.

Preferably, a sudden shrinkage and sudden expansion spoiler 324 is arranged in an ascending flow area formed by enclosing the high-level plate 322 and the low-level plate 323 of the first diversion sedimentation screen, so that the secondary enrichment effect of escaping foam is increased, fine coal slime is removed, and hammering foam-removing recovery at the rear end of a foam-removing area is facilitated.

3.2.2 bubble trap

As shown in fig. 6, each bubble removing area includes a plurality of bubble removing devices arranged along a radial direction of the cylindrical portion, and each bubble removing device includes a supporting unit, a hammering unit, a driving unit, and a flow guide unit.

The support unit includes brackets 348, a first bracket 348 is fixed above the plate body where the first diversion area and the central material collection area 31 intersect, and the other brackets 348 are fixed on the upper end surface of the elevated plate 322. In particular, the support 348 is tripod-shaped with the underlying support plate by two side bars, which not only provides support, but also does not interfere with the flow of material into and through the first flow guide region.

The hammering unit comprises a hammering foam-removing plate 343, a clean coal collecting groove 347 and a hammering rod 344. One end of the hammering rod 344 is hinged with the bracket 348, the other end is hinged with the hammering defoaming plate 343, and the clean coal collecting groove 347 is fixed on the side plate 321.

The driving unit comprises an impact pipe 341, a grooved roller 342 and a reciprocating spring 346, wherein the upper end of the impact pipe 341 is communicated with the feeding distribution groove 11, and the lower end of the impact pipe is opposite to the inner wall of the clean coal collecting groove 347 on the grooved roller 342. The middle part of the hammering rod 344 is connected with the middle parts of two side rods of a bracket 348 through a reciprocating spring 346, and the grooved roller 342 is arranged on the hammering rod 344 and is connected through a rotating shaft; the hammer blow plate 343 is hammered downward and the hammer rod 344 is impacted and deflected centrally by an amount less than the compression of the reciprocating spring 346. When the material in the feeding distribution groove 11 flows into the grooved roller 342 from the impact tube 341, the grooved roller 342 rotates at a non-uniform speed, the whole driving unit and the hammering unit increase in mass, the reciprocating spring 346 is in a compressed state, the hammering defoaming plate 343 is compressed into the clean coal collecting groove 347 until the material in the grooved roller 342 is too much, so that all the material is dumped out by the rotation of the roller, here, the hammering defoaming plate 343 is far away from the clean coal collecting groove 347 due to the energy accumulated by the reciprocating spring 346, and the hammering defoaming plate 343 beats the clean coal collecting groove 347 in a reciprocating manner by periodic motion, so that defoaming is realized. The coal slime water thrown out from the impact pipe 341 washes clean coal on the hammering foam-eliminating plate 343, so that the clean coal is discharged from a concentrate discharge port into a clean coal collecting groove 347 and is collected.

The flow guide unit comprises a flow guide bent plate 345, and the flow guide bent plate 345 is arranged at the lower section of the clean coal collecting groove 347 and is arranged in a down-flow interval surrounded by the high-level plate 322 and the low-level plate 323 of the first flow guide settling sieve. The mineralized foam enters the foam extinguishing area, rises to the inlet of the clean coal collecting groove 347 along the guide bent plate 345 in the roller pulse foam extinguishing device, and enters the clean coal collecting groove 347.

In conclusion, the non-settled fine coal slime and mineralized foam regenerated by the residual flotation reagent and the clean coal are collected to the central material collecting area 31 along with the water flow; then the water is shunted to the first diversion sedimentation sieve, and then passes through the second diversion sedimentation sieve, and the slime water containing fine slime flows to the edge of the central groove body 21 along the radial direction.

3.3 flow guiding settling zone

The diversion settling zone can have various schemes, which are specifically described as follows:

a3.3 first scheme of diversion settling zone

As shown in fig. 2 and 7, the diversion settlement area is a plurality of, and corresponds the setting at the district rear that disappears, and all is located between the interior border wall of central collecting area 31 and central cell body 21, the diversion settlement area includes second diversion settlement screen, is located the magnetic shower that gathers who sets for position department above the second diversion settlement screen.

A3.3.1 second diversion sedimentation screen

As shown in fig. 2 and 7, the second guiding sedimentation screen and the first guiding sedimentation screen are integrated, and the turbulence plates 325 are replaced by the suddenly-contracted and suddenly-expanded turbulence plates 324 in the first guiding sedimentation screen, so as to increase the disturbing sedimentation effect of the fine coal slurry, and the other structures are the same. Specifically, the outermost high-level plate 322 is at the same height as the side wall of the central trough body 21, so that the fluid after defoaming can overflow. The outer side wall of the upper end of the cylindrical part of the central groove body 21 is also annularly provided with an overflow groove 27. The first diversion sedimentation screen and the second diversion sedimentation screen are matched to realize multistage sedimentation of slime water, a two-stage thickener is avoided, the occupied area is reduced, and meanwhile, sufficient sedimentation time of fine mud is provided through the mode of collection of two-stage centers and multistage diversion sedimentation.

A3.3.2 magnetic gathering sprayer

As shown in fig. 7, the magnetic concentration sprayer comprises a first magnetic concentration injection pipe 351, a first magnetic powder feeding pipe 352 and a first distributor 353, and the magnetic concentration sprayer is arranged on the elevated plate 322 at the inlet above the second diversion and sedimentation sieve. The upper end of the first magnetic gathering injection pipe 351 is also communicated with the feeding distribution groove 11, the lower end of the first magnetic gathering injection pipe is communicated with the first distributing device 353, one end of the first magnetic powder feeding pipe 352 is connected with a pipeline at a magnetic powder supply position, and the other end of the first magnetic gathering injection pipe 351 is communicated with the first magnetic gathering injection pipe 351; the outlet at the lower end of the first distributing device 353 is in a fan-shaped arrangement and is separated by a plurality of partition plates, so that the magnetic material is uniformly gathered and flows down along the side wall of the guide plate fixed on the high-level plate 322, and the accelerated sedimentation of fine coal slime is realized. When the slime water passes through the second diversion sedimentation screen, the magnetism gathering sprayer sprays magnetic seeds to obtain high-efficiency sedimentation, the slime water flows around from the bottom of the high-level plate 322 step by step again, then overflows to a groove body formed between the high-level plate 322 and the low-level plate 323 of the next stage through the top of the low-level plate 323, in the process, the fine slime water can be fully settled through interference sedimentation of the turbulence sedimentation plate 325, is separated from water more thoroughly, is deposited on the lower plate body 320, is discharged through the first underflow discharge pipe 331, and overflows settled through the second diversion sedimentation screen are discharged into the overflow groove 27 to enter a washing process again as circulating water, so that closed-loop circulation is realized.

B3.3, second scheme of diversion settling zone

As shown in fig. 9-10, the diversion sedimentation area includes an annular diversion sedimentation screen and a magnetic gathering sprayer, and the annular diversion sedimentation screen is spirally arranged downwards around a central groove body 21. In this embodiment, the first diversion sedimentation screen in the defoaming area extends to the inner side wall of the central groove 21, and the slime water which is not settled at the first diversion sedimentation screen after defoaming overflows from the central groove 21 to the inlet of the annular diversion sedimentation screen. A magnetism gathering sprayer is arranged above the overflow outlet of each foam extinguishing area.

B3.3.1 annular diversion sedimentation screen

As shown in fig. 9-10, the annular diversion sedimentation screen includes an annular groove 371 spirally arranged around the central groove 21, second turbulence partition plates 3711 are sequentially arranged in the annular groove 371, a second underflow discharge outlet 3712 is arranged on a bottom plate between two adjacent second turbulence partition plates 3711, wherein the second turbulence partition plates 3711 increase the interference sedimentation effect of the fine coal slurry. Second inclined plate diversion discharge pipes 372 are arranged below the second underflow discharge ports 3712, outlets of all the second inclined plate diversion discharge pipes 372 are converged to the second underflow discharge pipe 373, namely settled materials are discharged from the second underflow discharge pipe 373, settled water passes through a second turbulence partition plate 3711 in the annular groove 371 and then is discharged from a second overflow discharge pipe 374 arranged at the tail end of the annular groove 371, and the water is used as circulating water to enter the washing and sorting process again, so that closed cycle is realized.

B3.3.2 magnetic gathering sprayer

As shown in fig. 9, the magnetism gathering sprayer includes a second magnetism gathering injection pipe 361, a second magnetic powder feeding pipe 362, and a second material distributor 363. The upper end of the second magnetic particle feeding pipe 362 is also communicated with the feeding distribution groove 11, the lower end of the second magnetic particle feeding pipe 361 is communicated with the second distributing device 363, one end of the second magnetic particle feeding pipe 362 is connected with a pipeline at a magnetic particle supply position, and the other end of the second magnetic particle feeding pipe 361 is communicated with the second magnetic particle feeding distribution groove; the outlet at the lower end of the second material distributor 363 is in a fan shape and is separated by a plurality of partition plates, so that magnetic materials collected at the outlet flow down along the side wall of the guide plate uniformly, and accelerated sedimentation of fine coal slime is realized. When the slime water passes through the annular diversion sedimentation screen, the magnetism gathering sprayer sprays magnetic seeds to obtain high-efficiency sedimentation.

C3.3, third scheme of diversion settling zone

As shown in fig. 11, water conservancy diversion settlement zone includes layer fall water conservancy diversion subsides sieve and gathers magnetic spray thrower, layer fall water conservancy diversion subsides sieve and falls the setting to the lower floor along central cell body 21 outer wall, and in this embodiment, the first water conservancy diversion of defoaming district subsides sieve and extends to the inside wall department of central cell body 21, and the coal slime water that does not subside in first water conservancy diversion subsides sieve department after the defoaming overflows central cell body 21 to in the layer fall water conservancy diversion subsides sieve. A magnetism gathering sprayer is arranged above the overflow outlet of each foam extinguishing area.

C3.3.1 layered descending diversion sedimentation screen

As shown in fig. 11, the laminar flow-guiding and flow-guiding settling sieve comprises a plurality of third flow-guiding settling subgroups which are sequentially arranged downwards along the outer wall of the central groove body 21, each third flow-guiding settling subgroup comprises a settling tank 391, a plurality of third flow-disturbing partition plates 3911 are alternately arranged in the settling tank 391, the third flow-disturbing partition plates 3911 can be alternately arranged on two side plates of the settling tank 391 according to the arrangement mode of the high-level plates 322 and the low-level plates 323, and the third flow-disturbing partition plates 3911 increase the interference settling effect of fine coal slime.

A third underflow discharge port is arranged on the bottom plate of each settling tank 391, a third inclined plate flow guide discharge pipe 392 is arranged below each settling tank 391, fine coal slime discharged from all the third underflow discharge ports in each settling tank 391 is collected, outlets of all the third inclined plate flow guide discharge pipes 392 are collected to the third underflow discharge pipe 393, and finally, the fine coal slime after settling is discharged from the third underflow discharge pipe 393.

The part of the coal slime water which is not settled passes through all the third turbulence partition plates 3911 in each third diversion settlement sub-group, and is output to the inlet of the next third diversion settlement sub-group from the connecting pipe 395 to the third diversion settlement sub-group at the lowest part, and the water which is completely settled is output from the third overflow discharge pipe 394 at the output end of the third diversion settlement sub-group at the lowest part and is used as circulating water to enter the washing and dressing process again, so that closed cycle is realized.

C3.3.2 magnetic gathering sprayer

As shown in fig. 11, the magnetism gathering sprayer comprises a third magnetism gathering injection pipe 381, a third magnetic powder feeding pipe 382 and a third distributing device 383, wherein the upper end of the third magnetism gathering injection pipe 381 is also communicated with the feeding distribution groove 11, the lower end of the third magnetism gathering injection pipe 383 is communicated with the third distributing device 383, one end of the third magnetic powder feeding pipe 382 is connected with a pipeline at a magnetic powder supply position, and the other end of the third magnetism gathering injection pipe 381 is communicated with the third magnetism gathering injection pipe 381; the outlet at the lower end of the third distributing device 383 is in a fan shape and is separated by a plurality of partition plates, so that magnetic materials are uniformly gathered at the outlet and flow down along the side wall of the guide plate, and accelerated sedimentation of fine coal slime is realized. When the slime water passes through the layer falling diversion sedimentation screen, the magnetism gathering sprayer sprays magnetic seeds to obtain high-efficiency sedimentation, and then the fine slime is fully sedimentated in the process and is separated from the water more thoroughly. In order to realize better settlement effect, in the scheme, the input ends of the third diversion settlement subgroups are respectively provided with a magnetism gathering sprayer.

As shown in fig. 12, the first distributor 353, the second distributor 363, and the third distributor 383 are all identical in structure. The multi-runner distributor is adopted, so that the distributor is more uniform, the stirring of the rakes is not needed in the working process, the rake pressing phenomenon is thoroughly solved, and the continuous and stable work of the thickener is ensured.

In summary, in the clean coal collecting assembly, the structure of the central collecting area 31 and the foam-removing area and the three diversion settling areas are combined at will to form different technical schemes.

The invention is not to be considered as limited to the specific embodiments shown and described, but is to be understood to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims.

Claims (10)

1. The utility model provides a do not have harrow enrichment facility of multistage settlement including laminar flow guiding sedimentation sieve, its characterized in that, including central cell body (21), central cell body (21) outside is provided with the water conservancy diversion settlement district, the water conservancy diversion settlement district is including laminar flow guiding sedimentation sieve and gather the magnetic shower, laminar flow guiding sedimentation sieve includes a plurality of third water conservancy diversion settlement subgroups that set gradually downwards along central cell body (21) outer wall, and in two adjacent settling tanks (391), lower settling tank (391) obtain the coal slime water that last settling tank (391) flowed out, and every third water conservancy diversion settlement subgroup includes settling tank (391), is provided with the third underflow bin outlet with the fine coal slime of subsiding on the bottom plate of settling tank (391), and the water after the complete settlement is exported from third overflow blow-off pipe (394) of the output end department of third water conservancy diversion settlement subgroup of below.

2. A multistage sedimentation rakeless concentrating apparatus comprising a laminar flow guiding and settling screen, according to claim 1, wherein a third inclined plate guiding and discharging pipe (392) is further provided under each settling tank (391), fine coal slime discharged from all the third underflow discharging ports in each settling tank (391) is collected, and the settled fine coal slime discharged from all the third inclined plate guiding and discharging pipes (392) is collected to the third underflow discharging pipe (393) and discharged.

3. The multistage sedimentation rakeless concentrating device comprises a layer-falling diversion sedimentation screen, and is characterized by further comprising a feeding assembly, a diversion assembly, a central collecting area and a defoaming area, wherein the coal slime water is mixed with a reagent through the feeding assembly, flows from the upper part of a central groove body to the inner side wall of the central groove body, then flows to the middle part of the central groove body through the diversion assembly, forms bubbles and carries fine coal slime to move upwards to a clean coal collecting assembly after reaction, the central collecting area and the defoaming area are located above an outlet of the diversion assembly, and the coal slime water containing the fine coal slime sequentially passes through the central collecting area, the defoaming area and the diversion sedimentation area.

4. The multistage sedimentation rakeless thickening device comprising a laminar flow guide sedimentation screen according to claim 3, wherein the feeding assembly comprises a feeding distribution groove (11), a main feeding pipe (12) and a reducer pipe (13); the reducing pipes (13) are uniformly distributed between the edge walls of the feeding distribution groove (11) and the central groove body (21), and the sudden shrinkage of the reducing pipes (13) is also provided with a medicament injection pipe (14).

5. The multistage sedimentation rake-free concentration device comprising the laminar flow guide sedimentation screen is characterized in that the flow guide assembly comprises a jet flow feeding pipe (22), a first guide plate (23) is arranged below the output end of the jet flow feeding pipe (22), and liquid output by the jet flow feeding pipe (23) flows to the center of the central groove body (21) through the first guide plate (23).

6. A multistage settling rakeless concentrating device comprising a laminar flow guiding settling screen according to claim 5, wherein the first flow guiding plate (23) is vortex-shaped.

7. The multi-stage sedimentation rakeless concentrating device comprising a layer-falling flow-guiding sedimentation screen is characterized in that a supporting column (25) is arranged below the feeding distribution groove (11), and the central material collection area (31) is of a circular groove structure with an upward opening and is sleeved on the supporting column (25).

8. The multistage sedimentation rakeless concentrating device comprising a descending diversion and sedimentation screen, wherein the foam-removing area comprises a first diversion and sedimentation screen and a foam remover positioned at a set position above the first diversion and sedimentation screen, the foam remover comprises a hammering unit and a driving unit, the hammering unit comprises a hammering foam-removing plate (343), a refined coal collecting groove (347) and a hammering rod (344), the hammering foam-removing plate (343) is hinged at one end of the hammering rod (344), a supporting unit is fixed on the first diversion and sedimentation screen, the other end of the hammering rod (344) is hinged on the supporting unit, the refined coal collecting groove (347) is fixed on a side plate (321) of the first diversion and sedimentation screen, one end of the driving unit is fixed on the supporting unit, and the other end of the driving unit is connected with the middle part of the hammering rod (344).

9. The multistage sedimentation rakeless concentrating device comprising a laminar flow guiding and settling screen, wherein the first flow guiding and settling screen comprises two side edge plates (321), a first flow guiding area is enclosed by a lower plate body (320), the lower plate body (320) is communicated with a first underflow discharging pipe (331) below the lower plate body through a first discharging valve (332), and a high plate (322) and a low plate (323) are alternately arranged between the two side edge plates (321).

10. The multistage sedimentation rake-free concentration device comprising the laminar flow-reducing flow-guiding sedimentation sieve, as claimed in claim 1, wherein the magnetic-gathering sprayer comprises a third magnetic-gathering injection pipe (381), a third magnetic powder feeding pipe (382) and a third distributing device (383), the upper end of the third magnetic-gathering injection pipe (381) is communicated with a feeding distribution groove (11) in the feeding assembly, the lower end of the third magnetic-gathering injection pipe is communicated with the third distributing device (383), one end of the third magnetic powder feeding pipe (382) is connected with a pipeline at a magnetic powder supply position, and the other end of the third magnetic-gathering injection pipe (381) is communicated with the third magnetic-gathering injection pipe (381).

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