CN111170548A - Purification module and coal mine underground water purification system thereof - Google Patents

Abstract

A purification module and a coal mine underground water purification system thereof are provided, wherein the purification module comprises: a mixing tank, a stirring tank and a settling tank; the stirring tank comprises a stirring tank body, a hollow stirring inner cavity is arranged in the stirring tank body, a third mounting disc, a second mounting disc, a stirring wheel, a swinging disc, another stirring wheel and a first mounting disc are sequentially arranged in the stirring inner cavity from bottom to top, the third mounting disc and the bottom of the stirring shaft can be circumferentially assembled in a rotating manner, the second mounting disc, the first mounting disc and the stirring cylinder can be circumferentially assembled in a rotating manner, and the two stirring wheels are sleeved outside the stirring cylinder, can axially slide with the stirring cylinder and cannot be circumferentially assembled in a rotating manner; the swing disc is sleeved and fixed outside the stirring cylinder; the mixing drum is close to the first mounting disc and is further provided with a through mixing drum drainage groove, the inside of the mixing drum is a hollow mixing inner drum, a water pumping auger is mounted in the mixing inner drum, and the outer edge of the water pumping auger is tightly attached to the inner wall of the mixing inner drum, sealed and sleeved on the mixing shaft.

Description

Purification module and coal mine underground water purification system thereof

Technical Field

The invention relates to a underground water treatment technology and a mining technology, in particular to a purification module and an underground coal mine water purification system thereof.

Background

In the process of underground coal mining, a large amount of underground wastewater is generated due to the infiltration of underground water, and the wastewater contains a large amount of solid particles, suspended matters, engine oil and the like, so that the underground wastewater cannot be directly used for underground production and use. At present, underground waste water is pumped out of the ground surface through a water pump, and is pumped back to an underground coal cutter after being purified through upper equipment on the ground surface, so that dust is removed and the underground coal cutter is used in life, and obviously, a large amount of energy consumption can be generated in the process. Although the technology for directly purifying the underground wastewater in the underground is available at present, the equipment has large volume and low purification efficiency, so that the purification of the underground wastewater cannot be met, and the produced purified water cannot meet the requirement of underground mining, so that the chicken ribs appear.

The applicant believes that the miniaturization of the equipment and the meeting of the demand for water for the downhole can be achieved as long as the purification efficiency is improved. According to the current experience, the reason that the underground wastewater is difficult to treat is mainly floaters, suspended matters, slow flocculation and the like, so that the purification efficiency can be effectively improved by solving the problems of treatment and flocculation of the floaters and the suspended matters. The magnetic flocculation precipitation technology in the prior art is combined, the water can be precipitated within a few minutes, and therefore the efficiency is high, and the treatment requirement of underground wastewater can be met.

Disclosure of Invention

In view of the above-mentioned defects of the prior art, the technical problem to be solved by the present invention is to provide a purification module and a coal mine underground water purification system, wherein a stirring tank of the purification module can increase the axial convection of a wastewater stirring tank body while stirring wastewater circumferentially, so as to increase the stirring efficiency and effect.

To achieve the above object, the present invention provides a purification module comprising:

the mixing tank is used for mixing the flocculating agent containing the magnetic seeds with the wastewater;

the stirring tank is used for stirring the flocculating agent and the wastewater, and the flocculating agent and the wastewater are actually mixed uniformly;

the sedimentation tank is used for settling the wastewater, so that the wastewater is flocculated under the action of a flocculating agent and magnetic seeds to obtain supernatant, and the purification is finished;

the stirring tank comprises a stirring tank body, a hollow stirring inner cavity is arranged in the stirring tank body, a third mounting disc, a second mounting disc, a stirring wheel, a swinging disc, another stirring wheel and a first mounting disc are sequentially arranged in the stirring inner cavity from bottom to top, the third mounting disc and the bottom of the stirring shaft can be assembled in a circumferential rotating mode, the second mounting disc, the stirring wheel, the swinging disc, the another stirring wheel and the first mounting disc are respectively sleeved outside the stirring cylinder, the second mounting disc, the first mounting disc and the stirring cylinder can be assembled in a circumferential rotating mode, and the two stirring wheels are sleeved outside the stirring cylinder and can be assembled in an axial sliding mode and cannot be assembled in a circumferential rotating mode; the swinging plate is sleeved and fixed outside the stirring cylinder;

the churn is close to first mounting disc department and still is provided with the churn water drainage tank that runs through, and the churn is inside to be hollow stirring inner tube, installs the auger that draws water in the stirring inner tube, draws water the auger outward flange and pastes tight sealed and suit with the inner wall of stirring inner tube and fix on the (mixing) shaft.

Preferably, the top of the stirring cylinder penetrates through the top of the stirring tank body and is assembled with the stirring tank body in a circumferentially rotatable and axially immovable manner, the stirring cylinder penetrates through one end of the stirring tank body and is assembled and fixed with the second stirring gear, the top of the stirring shaft penetrates through the stirring inner cylinder and the stirring support frame and is assembled and fixed with an output shaft of the stirring motor, the stirring shaft and the stirring support frame are assembled in a circumferentially rotatable and axially immovable manner, and the stirring support frame is fixed on the stirring tank body; the stirring shaft is fixedly sleeved with a first stirring gear, the first stirring gear and the second stirring gear are respectively in meshed transmission with a third stirring gear and a fourth stirring gear, the third stirring gear and the fourth stirring gear are sleeved on a stirring gear shaft, and the stirring gear shaft and the stirring support frame can rotate circumferentially and are in rotating fit.

Preferably, a stirring wheel shaft is arranged on the stirring wheel, stirring balls are arranged on the open end of the stirring wheel shaft in a spherical rolling manner, the stirring balls are attached to the end face of the swinging disc, and the end face of the swinging disc is an inclined plane with an upper potential difference and a lower potential difference.

Preferably, a first stirring spring is installed between the first mounting plate and the stirring wheel close to the first mounting plate, and the first stirring spring is sleeved outside the stirring cylinder and used for generating elastic force for blocking the stirring wheel pressed against the first mounting plate from moving towards the first mounting plate;

and a second stirring spring is arranged between the second mounting disc and the stirring wheel close to the second mounting disc, and the second stirring spring is sleeved outside the stirring cylinder and used for generating elastic force for blocking the stirring wheel pressed against the second stirring spring from moving to the second mounting disc.

Preferably, the top of the stirring inner cavity is communicated with the precipitation inner cavity through a precipitation water inlet pipe, the precipitation inner cavity is arranged in a precipitation tank body, the precipitation tank body belongs to the precipitation tank, a turbidity sensor and an electronic liquid level meter are further respectively arranged in the precipitation inner cavity, and the turbidity sensor is used for detecting the turbidity of water in the precipitation inner cavity and transmitting signals to the controller; the electronic liquid level meter is used for detecting the water level in the sedimentation inner cavity and inputting signals into the controller; the sediment inner cavity is positioned above the turbidity sensor and is communicated with the bottom of the purification drain pipe, and the purification drain pipe is used for pumping out the clear water after the sediment.

Preferably, an adsorption rod made of soft iron is installed in the inner cavity of the sediment, an electromagnetic coil is sleeved on the adsorption rod, and the electromagnetic coil generates a magnetic field after being electrified so as to magnetize the adsorption rod; after the sedimentation is finished, the electromagnetic coil is powered off, and the adsorption rod loses magnetism and falls into sludge in the sedimentation inner cavity.

Preferably, the mixing tank comprises a mixing tank body, the interior of the mixing tank body is a hollow mixing inner cavity, the bottom of the mixing tank body is a mixing conical shell, the bottom of the mixing inner cavity is communicated with one end of a feed pipe, the other end of the feed pipe is communicated with the interior of a material suction shell, the interior of the material suction shell is hollow and is provided with a first impeller, one end, far away from the end communicated with the feed pipe, of the interior of the material suction shell is communicated with the bottom of a valve cavity of a valve shell through a drainage pipe, a conical valve hole and a feed hole are further formed in the valve shell, the valve hole communicates the valve cavity with the feed hole, the feed hole is communicated with a flocculating; the valve hole is clamped and hermetically assembled with the valve core, and a valve body pressure spring is arranged between the bottom of the valve core and the bottom surface of the valve cavity; the first impeller is sleeved and fixed on one end of an impeller shaft, the other end of the impeller shaft is installed in the power shell and is assembled and fixed with the second impeller, the second impeller is installed in the power shell, two ends in the power shell are respectively communicated with the mixing inner cavity and the outlet of the water pump, and the inlet of the water pump is communicated with the purification water inlet pipe; the top of the mixing inner cavity is communicated with the bottom of the stirring inner cavity through a mixing pipe.

Preferably, the diameter of the mixing conical shell is gradually reduced from top to bottom, the bottommost part of the mixing conical shell is communicated with a mixing blow-off pipe, and the mixing blow-off pipe is communicated with an inlet of the mixing slurry pump; the mixing mud pump is used for pumping the mud in the mixing cavity into the magnetic separator;

the stirring cone shell is arranged at the bottom of a stirring tank body of the stirring tank, the diameter of the stirring cone shell is gradually reduced from top to bottom, the bottom of the stirring cone shell is communicated with a stirring drain pipe, the stirring drain pipe is communicated with an inlet of a stirring slurry pump, and the stirring slurry pump is used for pumping slurry in a stirring inner cavity into a magnetic separator;

the sedimentation tank body bottom of gunbarrel is provided with conical sedimentation awl shell, and the diameter of sedimentation awl shell from top to bottom diminishes gradually and its bottommost and deposit the blow off pipe intercommunication, and the sediment blow off pipe will deposit the mud pump in the inner chamber and pump to the magnetic separator through depositing the slush pump in.

The invention also discloses a coal mine underground water purification system which is applied with the purification module. And the magnetic flocculation precipitation technology is used for realizing the rapid precipitation of the underground wastewater, thereby realizing the high-efficiency water purification.

The invention has the beneficial effects that:

1. the invention has simple structure, directly separates a large amount of suspended matters from the overflow weir at the filter, thereby reducing the subsequent treatment difficulty, and can realize rapid precipitation and purification by combining the magnetic flocculation precipitation technology, thereby meeting the requirements of volume reduction and larger water supply. The separated suspended matters enter an independent treatment module for treatment, and the whole normal treatment efficiency is not influenced although the efficiency is low.

2. The filter can effectively separate large particles and solid particles with large mass through buoyancy, gravity and the filter screen, simultaneously can separate a large amount of floating objects and suspended objects from the overflow weir through the buoyancy of the overflow weir, the suspended objects and the floating objects, and then can independently purify the floating objects through the independent purification module, and the integral water supply amount cannot be influenced because the overflow amount is not high. Waste water gets into another purification module in a large number after getting rid of suspended solid and floater through the filter overflow to realize stable, efficient processing and supply water through this purification module, with the requirement that satisfies production in the pit, waste water purification.

4. The purification module of the invention mixes the wastewater, coagulant and magnetic seeds in the mixing inner cavity and then inputs the mixture into the stirring tank for fully stirring, thereby greatly improving the mixing efficiency and effect.

5. The magnetic separator of the invention extracts the magnetic seeds in the sludge containing the magnetic seeds, thereby realizing the recycling of the magnetic seeds, greatly reducing the consumption of the magnetic seeds and further reducing the process cost. In addition, the magnetic separator can scrape off the magnetic seeds adsorbed on the magnetic absorption plate through the upper scraper and the lower scraper, so that the magnetic seeds can flow back into the convergence pipe through a simpler structure and can be recycled finally.

Drawings

Fig. 1-2 are schematic structural views of a filter and purification module of the invention.

Fig. 2-13 are schematic views of the filter construction of the present invention. Wherein FIG. 6 is an enlarged view at F1 in FIG. 5; fig. 9-12 are schematic views of the cleaning mechanism.

Fig. 14-17 are schematic views of the purification module structure of the present invention. FIG. 15 is a schematic structural view of a first impeller and a second impeller; FIGS. 16 to 17 are schematic views showing the internal structure of the stirrer.

Fig. 18-25 are schematic views of the structure of the magnetic separator of the present invention. Wherein FIG. 24 is an enlarged view at F2 of FIG. 23; FIG. 25 is a schematic view of the structure of the convergent tube and the convergent shell.

Fig. 26-27 are schematic structural diagrams of the trigger arc plate and the power switch of the magnetic separator.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention.

Referring to fig. 1 to 25, the coal mine underground water purification system of the embodiment includes:

the filter A is used for removing floating objects, part of light suspended matters, large-particle solid impurities and the like in the wastewater;

the purification module B is used for settling suspended matters in the wastewater through medicaments (such as flocculating agents, acid-base agents and the like) with magnetic seeds and finally separating clear water with less impurities;

and the magnetic separator C is used for separating magnetic species from the sludge for reuse.

Most waste water enters the main purification module to be treated after passing through the filter, and water containing a large amount of floaters and suspended matters overflows through the overflow weir and enters the secondary purification module to be independently treated, so that the problem of low treatment efficiency caused by a large amount of floaters and suspended matters is solved. In this embodiment, the primary purification module and the secondary purification module are the same device, but the usage thereof is changed.

Referring to fig. 1 to 13, the filter a includes a filter side plate a120 and a filter shell a110, and the filter side plate a120 has two pieces which are respectively fixed at openings at two sides of the filter shell a 110; the top of the filtering shell A110 is provided with an overflow shell A130, an overflow weir A131 is formed between the inner side of the overflow shell A130 and the outer wall of the filtering shell A110, the overflow weir A131 is communicated with the top of a water collecting tank A141 in the water collecting shell A140, the bottom of the water collecting tank A141 is communicated with one end of an overflow pipe A210, the other end of the overflow pipe A210 is communicated with a purification water inlet pipe B140 of the secondary purification module, and therefore the wastewater output from the overflow weir is guided to the secondary purification module for treatment.

The inside of the filter shell A110 is a hollow filter cavity A111, the bottom of the filter cavity A111 is a V-shaped groove A112 with gradually-reduced width from top to bottom, a sludge packing auger A540 is installed in the V-shaped groove A112, the sludge packing auger A540 is sleeved and fixed on a sludge packing auger shaft A530, one end of the sludge packing auger shaft A530 penetrates through the filter shell A110 and then is assembled and fixed with an output shaft of a sludge packing auger motor A330 through a coupler, and the sludge packing auger motor A330 can drive the sludge packing auger A540 to rotate circumferentially after being started, so that sludge in the V-shaped groove A112 is conveyed to a direction far away from the sludge packing auger motor A330;

one end of the V-shaped groove A112, which is far away from the sludge auger motor A330, is provided with a through sewage discharge outlet A113, the bottom of the sewage discharge outlet A113 is communicated with one end of a first filtered sludge pipe A221, the other end of the first filtered sludge pipe A221 is communicated with an inlet of a filtered sludge pump A310, an outlet of the filtered sludge pump A310 is communicated with an inlet of a wringing machine through a second filtered sludge pipe A222, the wringing machine is used for carrying out solid-liquid separation on sludge, and the wrung solid is manually output to the ground for treatment or is backfilled underground; the separated liquid is directly introduced into a purification water inlet pipe B140 of the main purification module for treatment.

A spoiler A740 is mounted at the top of the V-shaped groove A112, a V-shaped spoiler groove A741 is arranged on one side of the spoiler A740 facing the V-shaped groove A112, and a space of at least 10 cm is reserved between the spoiler A740 and the inner wall of the V-shaped groove A112. The design is mainly to prevent the sludge in the choke groove A741 and the V-shaped groove A112 from polluting the water above the choke plate A740, and the subsequent treatment burden is large. Especially when filtering, carry mud to the drain through the mud auger simultaneously, through the blockking of spoiler, can greatly reduced by the mud of stirring sneak into the quantity of the aquatic above spoiler A740 again to prevent to cause great burden to follow-up processing, purification.

The top of the spoiler A740 is provided with a splitter plate A730, and the splitter plate A730 is provided with a splitter groove A731 bent towards the filtering water inlet pipe A260. When the underground water purification device is used, underground wastewater needing to be purified enters the filter cavity A111 from the filter water inlet pipe A260 and is sprayed to the diversion channel A731, so that potential energy of water flow is consumed through the diversion channel, convection power of water in the filter cavity is reduced, and the underground wastewater is mainly used for further separating large-mass solid particles in water and reducing subsequent purification burden.

The flow blocking plate A740 is provided with a filter screen A710 above, and the filter screen A710 is provided with countless through filter holes for filtering large-particle solid impurities in water, so that preparation is provided for subsequent precipitation and the burden of subsequent treatment is reduced. In the embodiment, the aperture of the filtering hole is 1-2 cm, so that most of solid impurities with the particle size larger than that of the filtering hole are filtered.

And a filtering drainage pipe A270 is arranged above the filtering net A710, and the filtering drainage pipe A270 is used for conveying the water filtered by the filtering net to a purifying water inlet pipe B140 of the purifying module B.

Preferably, in order to output the sludge in the V-shaped groove in time and prevent the sludge in the V-shaped groove from being mixed with the water entering the filtering cavity again due to excessive sludge, and greatly increase the subsequent purification burden, the applicant designs a sludge amount detection mechanism, wherein the sludge amount detection mechanism comprises a sludge diaphragm A920 and a sludge detection bag A910, the sludge diaphragm A920 has high elasticity and is installed at the opening end of the inner wall of the V-shaped groove, so that the opening end of the inner wall of the V-shaped groove A112 is sealed, the sludge detection bag A910 is installed at the inner wall of the V-shaped groove A112 and at the inner side of the sludge diaphragm A920, and the sludge detection bag A910 is internally provided with a hollow sludge inner bag A. In this embodiment, the sludge detection bag a910 and the sludge diaphragm a920 are respectively two and respectively installed on two inner walls of the V-shaped groove a 112; the two sludge detecting bags A910 are communicated with each other through a detecting bag connecting part A912.

The sludge detecting bag A910 is made of high-elasticity soft materials, such as rubber, silica gel, high-elasticity polyethylene fibers and the like. The inside of the sludge detecting bag a910 is filled with liquid, and in this embodiment, the inside of the sludge detecting bag a910 is filled with clean water. The interior of the sludge detection bag A910 is communicated with the floating cavity A411 of the detection assembly A400 through a detection connecting pipe A460. The detection assembly A400 comprises a first detection shell A410 and a second detection shell A420, the first detection shell A410 and the second detection shell A420 are respectively provided with a hollow floating cavity A411 and a detection cavity A421, the floating cavity A411 and the detection cavity A421 are sealed and divided, a floating block A430 is installed in the floating cavity A411 in a floating mode, the floating block A430 can float on liquid, and the floating block of the embodiment is made of foam. The top of the floating cavity A411 is at least 2-3 cm higher than the highest position of the sludge inner bag A911. A first magnet block A441 is fixed on the top surface of the floating block A430; install second magnet piece A442 in surveying the chamber A421, install between second magnet piece A442 top surface and the detection chamber A421 top inner wall and survey pressure spring A450, survey pressure spring A450 and be used for producing the elasticity that hinders second magnet piece A442 to shift up. A detection switch a320 is installed in the detection cavity a421, a travel switch may be used as the detection switch of this embodiment, and the trigger end of the detection switch a320 directly faces the top surface of the second magnet block.

The first magnet block and the second magnet block are magnetic, the first magnet block and the second magnet block are made of permanent magnets, and the same poles of the first magnet block and the second magnet block are opposite to each other so as to generate mutually repulsive magnetic force. In the initial state, the second magnet block a442 is located at the lowermost portion, and the detection switch is not triggered. Once the sludge detection bag A910 is extruded, liquid in the sludge inner bag A911 can enter the floating cavity A411, the liquid level in the floating cavity A411 rises, so that the floating block is driven by buoyancy to overcome the buoyancy of the first magnet block and the second magnet block to float upwards, the second magnet block overcomes the elasticity of the detection pressure spring by repulsive force between the second magnet block and the first magnet block to move upwards until the detection switch is triggered, the detection switch sends a signal to the controller, the sludge is judged to be required to be removed, and then the filtered sludge pump A310 and the sludge auger motor A330 are started to discharge the sludge in the V-shaped groove. After the trigger state of the detection switch is released, the filtered sludge pump A310 and the sludge auger motor A330 delay one end to stop running, and the delay time is one minute in the embodiment. Specifically, since the density of the sludge is greater than that of water, the density of the sludge is at least 1.8 times higher than that of water (in a turbid state) in the filter chamber, and the volume of the filter chamber is constant. Therefore, when the V-shaped groove is filled with sludge, the pressure applied to the sludge diaphragm is larger than that when no sludge exists, and the pressure can extrude the sludge detection bag A910 so as to detect the sludge through the detection assembly. The design can discharge the sludge in time, thereby preventing the situations that the sludge in the V-shaped groove is too much to cause repeated mixing with the wastewater, and the wastewater in the filter cavity is reduced to cause unstable subsequent purification and the like.

Preferably, after the filter screen is used for a period of time, the filter holes of the filter screen are easy to block, and once the filter screen is blocked, the filter efficiency and the filter effect are greatly influenced, so that the applicant designs a cleaning mechanism for backwashing the filter screen. The cleaning mechanism comprises spray heads A251, water distributors A250 and a high-pressure hard pipe A230, wherein high-pressure water flow is introduced into the high-pressure hard pipe A230, the water distributors A250 uniformly distribute the high-pressure water flow to inlets of the spray heads A251, and the water flow is sprayed out through the spray heads A251, so that the top surfaces of the filter screens A710 are washed, and blocked filter holes are flushed away in a backwashing mode. The inlet of the water separator A250 is communicated with the bottom of the high-pressure hard pipe A230, and the high-pressure hard pipe A230 is fixed on the water separator A250;

the outer surface of the high-pressure hard pipe A230 is provided with a clamping tooth part A231, the clamping tooth part A231 forms a rack on the high-pressure hard pipe, the clamping tooth part A231 is in meshed transmission with a gear A610 to form a gear-rack transmission mechanism, the gear A610 is sleeved and fixed on a cleaning gear shaft A560, the cleaning gear shaft A560 and two first movable vertical plates A171 can be assembled in a circumferential rotating mode, one end of the cleaning gear shaft A is connected and fixed with an output shaft of a cleaning motor A370 through a coupler, and the cleaning motor A370 can drive the gear A610 to rotate in the circumferential direction after being started.

The first movable vertical plate A171 is fixed on the movable seat A170, the cleaning motor A370 is installed on the movable seat A170, the movable seat A170 is assembled with at least two filter screws A510 in a screwing mode through threads, and two ends of each filter screw A510 are assembled with the two vibrating vertical plates A161 in a rotating mode and in a non-axial-moving mode respectively; one ends of the two filter screws A510 penetrate through one of the vibrating vertical plates A161 and are respectively assembled and fixed with the side shift belt wheels A811, and the two side shift belt wheels A811 are connected through a side shift belt A810 to form a belt transmission mechanism; one end of one of the filter screws A510 is also fixedly assembled with an output shaft of the side-shifting motor A340 through a coupler, and the side-shifting motor can start the filter screw A510 to rotate circumferentially after being started, so that the movable seat A170 is driven to move axially along the filter screw A510 through threads.

The two vibrating risers a161 are respectively installed at two ends of the vibrating plate a160, and the vibrating plate a160 is installed with a vibrating motor a350, which can generate high-frequency vibration to the vibrating plate a160 after being started. The vibration plate A160 is assembled and fixed with the top of the vibration rod A520, the bottom of the vibration rod A520 penetrates through the upper mounting plate A721 and then is assembled and fixed with the filtering edge A711, the waterproof bag A820 is mounted below the filtering edge A711, the upper end and the lower end of the waterproof bag A820 are respectively fixed on the filtering edge A711 and the lower mounting plate A722, the filtering edge A711 is arranged on the edge of the filtering net A710, the upper mounting plate A721 and the lower mounting plate A722 are respectively fixed on the inner wall of the filtering cavity, the waterproof bag A820 is made of a high-elasticity material and is internally provided with a hollow waterproof inner cavity A821, the upper end and the lower end of the waterproof inner cavity A821 are respectively fixed with an upper support plate A831 and a lower support plate A832, the upper support plate A831 and the lower support plate A832 are respectively assembled and fixed with one end of the waterproof rod A851 and one end of the waterproof cylinder A852, the other end of the waterproof rod A851 is arranged in the waterproof cylinder A852 and can be axially assembled, The part between the lower supporting plates A832 is sleeved with a vibration compression spring A840, and the vibration compression spring A840 is used for generating elastic force for preventing the upper supporting plate A831 and the lower supporting plates A832 from approaching each other. In use, the vibration motor is started, so that the vibration rod a520 generates high-frequency vibration to the filter screen a710, and the vibration compression spring a840 is used for enabling the filter screen a710 to resonate with the vibration motor, so as to increase the vibration amplitude. Through the vibration, the impurities adsorbed on the bottom surface of the filter screen can be vibrated down, so that the filter screen is further cleaned.

Preferably, the two vibrating vertical plates a161 are further respectively provided with a first travel switch a361 and a second travel switch a362, trigger ends of the first travel switch a361 and the second travel switch a362 respectively face the moving seat a170, the moving seat a170 can respectively trigger the first travel switch a361 and the second travel switch a362, and the first travel switch a361 and the second travel switch a362 are triggered to transmit signals to the controller, so that it is determined that the moving seat reaches the maximum displacement point.

Preferably, a first limit block a233 and a second limit block a234 are further fixed on the high-pressure hard tube a230, the first limit block a233 and the second limit block a234 are respectively opposite to trigger ends of a third travel switch a363 and a fourth travel switch a364 mounted on the movable seat, the first limit block a233 and the second limit block a234 can trigger the third travel switch a363 and the fourth travel switch a364 respectively, and signals are transmitted to the controller after the third travel switch a363 and the fourth travel switch a364 are triggered, so that it is determined that the high-pressure hard tube reaches a maximum displacement point. The third travel switch A363 is installed on the limiting installation plate A172, and the limiting installation plate A172 is fixed on the two first moving vertical plates A171.

Preferably, the anti-slip clamping groove a235 is arranged on the side of the high-voltage hard tube a230 not provided with the clamping tooth portion a231, the anti-slip clamping groove a235 is in clamping assembly with an anti-slip clamping tooth a681 on a locking plate a680, so that the high-voltage hard tube a230 is fixed in the axial direction, the locking plate a680 is fixed at one end of a locking rod a550, the other end of the locking rod a550 passes through a wave spring a670 and a switch through groove a621 respectively and then is assembled and fixed with a driving inclined block a650, the switch through groove a621 is arranged on a switch block a620, mutually contacting surfaces of the switch block a620 and the driving inclined block a650 are respectively provided with a switch inclined surface a622 and a driving inclined surface a651 which are mutually attached, one end of the switch block a620 is assembled and fixed with one end of a movable telescopic shaft a381 of the movable electromagnet a380, and after the movable electromagnet a380 is started, the movable telescopic; the moving electromagnet A380 is fixed on the moving seat A160.

The switch block A620 is clamped with the switch chute A1711 and can be assembled in a sliding mode respectively, the switch chute A1711 is arranged on the first movable vertical plate A171, one end, far away from the movable electromagnet, of the switch block A620 is fixedly assembled with one end of the switch guide shaft A640, and the other end of the switch guide shaft A640 is sleeved with the switch pressure spring A630 and then penetrates through the second movable vertical plate A173 and can be assembled with the second movable vertical plate A173 in an axial sliding mode. The switching compression spring a630 is used for generating an elastic force for pushing the switching block a620 to the moving electromagnet.

In an initial state, the second limit block a234 triggers the fourth travel switch a364, and the locking plate a680 and the high-pressure hard tube a230 are pressed together by the elastic force of the wave spring a670, so that the high-pressure hard tube a230 is relatively fixed. The water separator is now at the very top, preferably at the top of the filter chamber a 111.

When the filter screen needs to be cleaned, the filter is stopped to be used firstly, then water in the filter cavity is discharged completely, then the movable electromagnet A380 is electrified, the switch block A620 overcomes the elasticity of the switch pressure spring and pushes the switch pressure spring to the second movable vertical plate A173, so that the switch block drives the driving inclined block A650 to drive the locking plate to move away from the high-pressure hard pipe by overcoming the elasticity of the wave spring through the switch inclined surface A622, the locking plate is separated from the high-pressure hard pipe, the cleaning motor A370 is started, the cleaning motor A370 drives the high-pressure hard pipe to move downwards until the first limiting block triggers the third travel switch A363, and at the moment, the cleaning motor A370 and the movable electromagnet stop running. High-pressure water flow is introduced into the high-pressure hard pipe, the lateral movement motor A340 is started, and the movable base A170 is driven to axially reciprocate along the filter screw A510, so that the spray head 251 is carried to move along the filter screen so as to continuously wash the filter screen. And simultaneously, the vibration motor is started to apply high-frequency vibration to the filter screen so as to increase the cleaning effect.

Preferably, the top of the overflow case a130 is closed by a top plate a150, a gap is formed between the top plate a150 and the vibration plate a160, and a top plate through groove a151 and a vibration plate through groove a162 for passing the high-pressure hard tube a230 are respectively formed on the top plate a150 and the vibration plate a 160.

The movable seat A170 is provided with a movable mounting hole A174, a movable plug A960, a movable pressure spring A970 and a movable pressure lever A980 are sequentially mounted in the movable mounting hole A174 from top to bottom, a movable large end A981 is arranged at one end, in contact with the movable pressure spring A970, of the movable pressure lever A980, the movable large end A981 is pressed between the movable plug A960 and the movable large end A981, and the movable plug A960 is fixed on the movable mounting hole A174; the bottom of the movable pressure lever A980 penetrates through the movable mounting hole A174 and then is assembled with the movable ball A990 in a spherical rolling mode, and the movable ball A990 is tightly pressed with the vibration plate A160. In use, the frictional damping between the moving seat a170 and the vibration plate a160 is reduced by the moving ball a 990.

Preferably, in order to find that the filter screen is blocked and needs to be cleaned in time, the applicant sets the filter screen to be in an arc shape recessed towards the V-shaped groove, and further sets a detection mechanism, the detection mechanism includes a detection assembly a400 and a detection shell a940, the detection shell a940 is fixed in the filter cavity a111, one end of the detection shell a940, which is far away from the inner wall of the filter cavity, is opened, the open end is sealed by a detection membrane a930, the detection membrane a930 has high elasticity, a detection bag a950 is installed inside the detection shell a940, a hollow detection inner cavity a951 is arranged inside the detection bag a950, and liquid, which may be water, is filled inside the detection inner cavity a 951. The detection inner cavity A951 is communicated with the floating cavity A411 of the detection assembly A400 through a detection pipe A46, and the topmost part of the floating cavity A411 is 2-3 cm higher than the detection inner cavity A411; the detection bag A950 is made of soft high-elasticity materials. During the use, because the filter screen undercut sets up, consequently its bottommost takes place to block up most easily, water can only be close to from filter screen A710 and filter the edge outflow after blockking up, and the inflow of filtering the inlet tube keeps stable, therefore the water pressure of filter screen below increases, water pressure extrusion detects bag A950, make in the detection bag liquid get into the showy chamber A411 that corresponds with it, the detection switch that corresponds up to it is triggered, the controller obtains the signal this moment, judge for needing to wash, then get into the cleaning procedure. In actual use, a plurality of filters can be arranged, so that when one filter is cleaned, other filters are continuously used, and the stability of water supply is ensured.

Referring to fig. 14 to 17, the purification module B includes:

a mixing tank B100 for mixing the magnetic seed-containing flocculant with the wastewater;

the stirring tank B300 is used for stirring the flocculating agent and the wastewater, and the flocculating agent and the wastewater are actually mixed uniformly;

and the settling tank B400 is used for settling the wastewater, so that the wastewater is flocculated under the action of a flocculating agent and magnetic seeds to obtain supernatant, and the purification is finished.

The mixing tank B100 comprises a mixing tank B110, a hollow mixing inner cavity B111 is arranged in the mixing tank B110, a mixing conical shell B120 is arranged at the bottom of the mixing tank B110, the diameter of the mixing conical shell B120 gradually decreases from top to bottom, the bottommost part of the mixing conical shell B120 is communicated with a mixing blow-off pipe B130, and the mixing blow-off pipe B130 is communicated with an inlet of a mixing slurry pump, so that sludge is conveyed into a magnetic separator C;

mix inner chamber B111 bottom and filling tube B280 one end intercommunication, the filling tube B280 other end with inhale the inside intercommunication of material shell B260, inhale the inside cavity of material shell B260 and install first impeller B270, inhale material shell B260 inside and keep away from and pass through drainage tube B250 and valve casing B220's valve pocket B223 bottom intercommunication with filling tube intercommunication one end, still be provided with conical valve opening B222, feed port B221 on the valve casing B220, valve opening B222 communicates valve pocket B223 and feed port B221, feed port B221 and the inside flocculating agent intercommunication of flocculation tank B210, and it has the magnetism kind to mix in the flocculating agent.

The valve hole B222 is clamped and hermetically assembled with the valve core B230, a valve body pressure spring B240 is arranged between the bottom of the valve core B230 and the bottom surface of the valve cavity B223, and the valve body pressure spring B240 is used for generating elastic force for pushing the valve core to the valve hole, so that the valve core is kept to seal the valve hole.

The first impeller B270 is sleeved and fixed on one end of an impeller shaft B290, the other end of the impeller shaft B290 is installed in the power shell B160 and is assembled and fixed with the second impeller B170, the second impeller B170 is installed in the power shell B160, two ends in the power shell B160 are respectively communicated with the mixing inner cavity B111 and the outlet of the water pump B150, and the inlet of the water pump B150 is communicated with the purification water inlet pipe B140, so that the wastewater conveyed from the filter is conveyed into the mixing inner cavity; the water pump is used for sucking water in the filtering cavity. When the water-saving mixing device is used, water pumped by the water pump drives the second impeller to rotate circumferentially and then enters the mixing inner cavity; the second impeller drives the first impeller B270 to rotate circumferentially through the impeller shaft B290, negative pressure (similar to a vane pump) for sucking is generated in the valve cavity when the first impeller B270 rotates circumferentially, the valve core is driven by the negative pressure to overcome the elasticity of the valve body pressure spring to move downwards, and accordingly, a flocculating agent in the flocculation tank B210 enters the feed pipe B280 and then enters the mixing inner cavity to be mixed with wastewater.

The top of the mixing inner cavity B111 is communicated with the bottom of the mixing inner cavity B311 through a mixing pipe B180, the mixing inner cavity B311 is arranged in a mixing tank body B310 of a mixing tank B300, a mixing conical shell B313 is arranged at the bottom of the mixing tank body B310, the diameter of the mixing conical shell is gradually reduced from top to bottom, the bottom of the mixing conical shell B313 is communicated with a mixing drainage pipe B314, the mixing drainage pipe B314 is communicated with an inlet of a mixing slurry pump, and the mixing slurry pump is used for pumping slurry in the mixing inner cavity B311 into a magnetic separator C.

A third mounting disk B363, a second mounting disk B362, a stirring wheel B370, a swinging disk B380, another stirring wheel B370 and a first mounting disk B361 are sequentially mounted in the stirring inner cavity B311 from bottom to top, the third mounting disk B363 and the bottom of the stirring shaft B340 can be circularly assembled in a rotating manner, the second mounting disk B362, the stirring wheel B370, the swinging disk B380, the other stirring wheel B370 and the first mounting disk B361 are respectively sleeved outside the stirring cylinder B350, the second mounting disk B362, the first mounting disk B361 and the stirring cylinder can be circularly assembled in a rotating manner, and the two stirring wheels B370 are sleeved outside the stirring cylinder B350 and can be axially slid with the stirring cylinder B and can not be circularly assembled in a rotating manner; the swinging plate B380 is sleeved and fixed outside the mixing drum B350.

A through mixing drum drainage tank B351 is further arranged at the mixing drum B350 close to the first mounting plate B361, a hollow mixing inner drum B352 is arranged inside the mixing drum B350, a water pumping auger B530 is mounted inside the mixing inner drum B352, and the outer edge of the water pumping auger B530 is tightly attached to the inner wall of the mixing inner drum B352, sealed and sleeved with the mixing inner drum B352 and is fixedly arranged on the mixing shaft B340; when the pumping auger B530 rotates circumferentially, water at the bottom of the stirring inner cavity can be lifted upwards along the stirring inner cylinder B352 until the water is discharged to the stirring inner cylinder B311 through the stirring cylinder drainage tank B351. This design can increase the convection current of waste water in the vertical direction to increase mixing efficiency and uniformity.

The top of the stirring cylinder B350 penetrates through the top of the stirring tank body B310 and is assembled with the stirring tank body B310 in a circumferentially rotatable and axially immovable manner, one end of the stirring cylinder B350, which penetrates through the stirring tank body B310, is assembled and fixed with a second stirring gear B332, the top of the stirring shaft B340 penetrates through the stirring inner cylinder B352 and the stirring support frame B312 and then is assembled and fixed with an output shaft of a stirring motor B320 through a coupler, the stirring shaft B340 can drive the stirring shaft to circumferentially rotate after being started, the stirring shaft B340 and the stirring support frame B312 can circumferentially rotate and axially immovable and are assembled, and the stirring support frame B312 is fixed; a first stirring gear B331 is fixedly sleeved on the stirring shaft B340, the first stirring gear B331 and the second stirring gear B332 are respectively in meshed transmission with a third stirring gear B333 and a fourth stirring gear B334, the third stirring gear B333 and the fourth stirring gear B334 are respectively sleeved on a stirring gear shaft B550, and the stirring gear shaft B550 and the stirring support frame B312 can be circumferentially and rotatably assembled. During the use, agitator motor starts to drive churn, (mixing) shaft respectively the circumferencial rotation, thereby make stirring wheel B370 stir waste water so that waste water and flocculating agent flash mixed.

The stirring wheel B370 is provided with a stirring wheel shaft B371, the open end of the stirring wheel shaft B371 is provided with a stirring ball B372 in a spherical rolling way, the stirring ball B372 is tightly attached to the end surface of the swinging disk B380, and the end surface of the swinging disk B380 is an inclined surface with a difference in vertical potential, so that the stirring wheel B370 can be driven to move in the axial direction when the swinging disk rotates circumferentially. A first stirring spring B510 is installed between the first mounting plate B361 and the stirring wheel close to the first mounting plate B361, and the first stirring spring B510 is sleeved outside the stirring cylinder B350 and used for generating elastic force for blocking the stirring wheel B370 pressed against the first stirring spring B to move towards the first mounting plate B361. In use, the stirring wheel B370 reciprocates up and down in the axial direction under the driving of the swinging disk, so that the stirring effect is increased.

A second stirring spring B520 is installed between the second mounting plate B362 and the stirring wheel B370 close to the second mounting plate B, and the second stirring spring B520 is sleeved outside the stirring cylinder B350 and is used for generating elastic force for blocking the stirring wheel B370 pressed against the second mounting plate B362 from moving. In use, the stirring wheel B370 reciprocates up and down in the axial direction under the driving of the swinging disk, so that the stirring effect is increased.

Preferably, the stirring inner cylinder B352 is internally fixed with a stirring retaining ring B353, and the stirring retaining ring B353 and the stirring shaft are circumferentially rotatably and hermetically assembled, which mainly increases the stability of the stirring shaft.

Stirring inner chamber B311 top is through deposiing inlet tube B431 and sediment inner chamber B411 intercommunication, and sediment inner chamber B411 sets up in the sediment jar body B410, and the sediment jar body B410 belongs to sediment jar B400, still install turbidity sensor B440, electronic level gauge B420 in the sediment inner chamber B411 respectively, turbidity sensor B440 is used for surveying the turbidity of sediment inner chamber water to carry the signal to the controller, thereby judge whether the water of sediment inner chamber deposits and accomplishes. The electronic liquid level meter is used for detecting the water level in the sedimentation inner cavity B411 and inputting signals into the controller. The sedimentation inner cavity B411 is positioned above the turbidity sensor B440 and is also communicated with the bottom of a purification drain pipe B432, and the purification drain pipe B432 is used for pumping out the settled clean water. In actual use, a plurality of settling tanks B400 can be prepared for one-by-one use so as to ensure the requirements of settling and water supply.

Preferably, in order to increase the precipitation efficiency, an adsorption rod made of soft iron can be installed in the precipitation inner cavity, an electromagnetic coil is installed on the adsorption rod, and a magnetic field is generated after the electromagnetic coil is electrified, so that the adsorption rod is magnetized, and the magnetic seed is adsorbed by magnetic force to accelerate precipitation and flocculation. Through actual measurement, the flocculation time can reach about 5 minutes at present, and the efficiency is extremely high. After the adsorption is finished, the electromagnetic coil is powered off, and the adsorption rod loses magnetism and falls into the sludge in the sedimentation inner cavity. The bottom of the sedimentation tank body B410 is also provided with a conical sedimentation conical shell B412, the diameter of the sedimentation conical shell B412 is gradually reduced from top to bottom, the bottommost part of the sedimentation conical shell B412 is communicated with a sedimentation drainage pipe B413, and the sedimentation drainage pipe B413 pumps sludge in the sedimentation inner cavity into the magnetic separator C through a sedimentation slurry pump.

Referring to fig. 17-25, the magnetic separation device C includes a magnetic separation plate C110, a magnetic separation frame C120, and a magnetic separation tank C130, the magnetic separation tank C130 has a magnetic separation cavity C131 therein, two ends of the magnetic separation tank C130 are open, and two open ends are respectively assembled with one set of magnetic separation plate C110 and one set of magnetic separation frame C120, and the two sets of magnetic separation plate C110 and one set of magnetic separation frame C120 are provided;

two open ends of the magnetic separation cavity C131 can be circumferentially rotated and hermetically assembled with a magnetic sealing disc C540 respectively, a plurality of magnetic plate installation seats C330 are installed on the magnetic sealing disc C540 along the circumferential direction of the magnetic separation cavity C540, the two coaxial magnetic plate installation seats C330 are respectively fixedly assembled with two ends of a magnetic adsorption plate C340, one end, far away from the magnetic separation cavity C131, of each magnetic plate installation seat C330 is fixedly assembled with a magnetic protection cylinder C320, a magnetization shaft C332 is installed in each magnetic protection cylinder C320, a coil C220 is sleeved outside each magnetization shaft C332, the coil C220 is installed in a magnetic protection inner cavity C321 of each magnetic protection cylinder C320, a magnetic field is generated after direct current is introduced into each coil C220 to magnetize the magnetization shaft C332, the magnetization shaft C332 is fixed at the end part of each magnetic plate installation seat C330, and the magnetic sealing disc C540 can be circumferentially rotated and hermetically assembled.

The magnetization axis C332, the magnetic plate mounting seat C330 and the magnetic adsorption plate C340 are all made of soft iron materials or integrally made parts made of soft iron materials are contained in the magnetization axis C332, the magnetic plate mounting seat C330 and the magnetic adsorption plate C340. When the magnetization axis C332 is magnetized, the magnetization axis C332, the magnetic plate mount C330, and the magnetic adsorption plate C340 can simultaneously carry magnetism, so that the magnetic adsorption plate C340 adsorbs magnetic species in the sludge.

The magnetic separation cavity C131 is internally communicated with one end of a sludge feeding pipe C440 and one end of a sludge discharging pipe C410 respectively, and sludge to be subjected to magnetic separation enters the magnetic separation cavity C131 through the sludge feeding pipe C440; and discharging the sludge subjected to magnetic separation into a screw extruder through a sludge discharge pipe C410 for solid-liquid separation, and refluxing the separated wastewater into a mixing inner cavity. Because certain magnetic species still exist in the wastewater, the wastewater can be reused in a backflow mode.

One end of the magnetic protection cylinder C320 far away from the magnetic plate mounting seat C330 is fixedly assembled with the holding disc C550, the holding disc C550 is fitted with the inside of the magnetic separation frame C120 in a circumferentially rotatable and sealed manner, the end surface of one end of the holding disc C550 far away from the magnetic protection cylinder C320 is also coaxially assembled and fixed with a rotary bull gear C530, the rotary bull gear C530 is in meshed transmission with a rotary pinion gear C520, the rotary pinion gear C520 is sleeved and fixed on one end of a separation adapter shaft C350, the other end of the separation adapter shaft C350 passes through the magnetic separation partition plate C110 and then is assembled and fixed with a second separation belt wheel C512, the second separation pulley C512 is connected to the first separation pulley C511 by a separation belt C510 and constitutes a belt transmission mechanism, the first separating belt wheel C511 is sleeved and fixed on the separating driving shaft C310, the separating driving shaft C310 is assembled and fixed with the output shaft of the separating motor C210, the separating motor C210 may be a hollow shaft motor, and at this time, the separating driving shaft C310 penetrates through the hollow output shaft and is assembled and fixed with the hollow output shaft. Separation motor C210 can drive rotatory pinion rotation after starting to the rotatory gear wheel of drive rotates, just also makes magnetic seal dish circumferential rotation, installs the magnetic adsorption board C340 on the magnetic seal dish this moment and constantly shuttles back and forth in the mud in magnetic separation chamber C131, thereby constantly adsorbs on magnetic adsorption board C340 through magnetic force with the magnetism kind.

Two magnetic separation board C110 respectively with assemble fixedly with assembling pipe C420, assemble pipe C420 inside for hollow assemble chamber C421 and assemble pipe C420 one end and wear out one of them magnetic separation board C110 back and the sealed intercommunication of magnetic reflux pipe C430 one end, the magnetic reflux pipe C430 other end inserts the import of backward flow mud pump, and the export of backward flow mud pump inserts in the stirring inner chamber to the magnetic seed that will export in assembling chamber C421 flows back to the stirring inner chamber and carries out used repeatedly. The magnetic sealing disc C540 and the retaining disc C550 are respectively assembled with the converging tube C420 in a circumferential rotating and sealing way.

The convergence shell C450 is installed at the position, corresponding to the magnetic adsorption plate C340, of the convergence pipe C420, a hollow convergence groove C451 is formed inside the convergence shell C450, the convergence groove C451 is communicated with a convergence cavity C421, and one end, far away from the magnetic return pipe C430, of the convergence cavity C421 is a closed end.

The inner wall of the converging groove C451 is fixedly assembled with a lower supporting plate C760, the lower supporting plate C760 is axially assembled with a lower movable shaft C770 in a sliding manner, the bottom of the lower movable shaft C770 penetrates through the lower supporting plate C760 and then is fixedly assembled with a limit nut C771, and the limit nut cannot penetrate through the lower supporting plate C760; the top of the lower movable shaft C770 is sleeved with the lower movable pressure spring C742 and then assembled and fixed with the lower fixed plate C721, the top surface of the lower fixed plate C721 is fixed with the lower scraping plate C720, and the lower scraping plate C720 can be attached to the bottom end surface of the magnetic adsorption plate C340 to scrape off the magnetic seeds adsorbed on the bottom end surface of the magnetic adsorption plate.

The last scraper blade C710 that can paste tightly with magnetism adsorption plate C340 top face is installed to lower scraper blade C720 top, thereby go up scraper blade C710 and the magnetism adsorption plate C340 top face paste tightly scrape the magnetic seed that adsorbs on magnetism adsorption plate C340 top face, and the magnetic seed that scrapes on the magnetism adsorption plate C340 all drops to in assembling groove C451, then exports through assembling chamber C421.

The upper scraper C710 is fixed on an upper fixing plate C711, the upper fixing plate C711 is fixedly assembled with the bottom of an upper movable shaft C730, the top of the upper fixing plate C730 is installed in a movable sliding hole C132, a movable big end C731 is fixed on the end of the upper fixing plate C730, the movable big end C731 and the movable sliding hole C132 can be assembled in an axial sliding mode, the movable big end C731 and the bottom of an upper movable pressure spring C741 are pressed, the upper movable pressure spring C741 and the bottom of a magnetic separation plug C750 are pressed, the magnetic separation plug is installed and fixed in the movable sliding hole C132, the movable sliding hole C132 is arranged at the top of a magnetic separation tank C130, and the upper movable shaft C730 can be assembled in an axial sliding mode. The magnetic attraction plate C340 is not horizontally inserted but is rotated around the magnetic seal disk during the process of being inserted between the upper blade C710 and the lower blade C720, so that the gap between the upper blade C710 and the lower blade C720 needs to be adjustable so as to be effectively attached to the end face of the magnetic attraction plate to scrape off the magnetic species attracted by the magnetic attraction plate. The above structure is to realize the adjustable gap between the upper scraper C710 and the lower scraper C720.

Preferably, in order to prevent the magnetic attraction plate C340 from causing too much impact on the upper blade C710 and the lower blade C720 or requiring a large adjustable gap between the upper blade C710 and the lower blade C720, the applicant further sets the magnetic attraction plate to rotate along the circumferential direction thereof at a small angle, specifically as follows:

the magnetic plate mounting seat C330 penetrates through one end of the magnetic sealing disc 540 to be fixed with a first spring block C331, the first spring block C331 is connected with a second spring block C541 through a magnetic separation spring C610, the magnetic separation spring C610 is used for providing elastic damping for rotation of the magnetic plate mounting seat C330, and the magnetic separation spring C610 drives the magnetic plate mounting seat C330 to reversely reset through elasticity after the torsional force borne by the magnetic plate mounting seat C330 disappears. The design enables the magnetic plate mounting seat to be capable of self-transmitting at a small angle, so that the magnetic plate mounting seat can be better matched with the upper scraper and the lower scraper.

Preferably, the power of the coil C220 is cut off during the process from the time when the magnetic adsorption plate C340 enters between the upper scraper and the lower scraper to the time when the magnetic adsorption plate C is separated from between the upper scraper and the lower scraper, or the power of the coil corresponding to the magnetic adsorption plate C340 is cut off after the magnetic adsorption plate C enters above the convergence groove C451, so that the magnetic adsorption plate C340 loses magnetism to facilitate the magnetic seed scraping.

Preferably, the power supply line of the coil may be integrated on the holding disk C550 and the electric slip ring is coaxially mounted on the holding disk C550, the stator of the electric slip ring is fixed on the holding disk C550, and the rotor is electrically connected with the external power supply line, thereby ensuring the normal power supply of the coil.

Referring to fig. 26 to 27, specifically, a push type power switch C260 for controlling the current on/off of the coil C220 is installed on the magnetic protection cylinder C320, one end of the coil is electrically connected to a second conductive ring C252 sleeved on the outer edge of the holding disc C550, the second conductive ring C252 is electrically connected to a first conductive ring C251 and is circumferentially rotatably assembled in a contact manner, the first conductive ring C251 is electrically connected to one end of a negative lead C232, and the other end of the negative lead is electrically connected to the negative pole of the dc power supply;

the other end of the coil is connected with a power switch C260 in series and then is in conductive connection with a rotor of an electric slip ring C240, the rotor of the electric slip ring is fixed on the inner sides of a holding disc C550 and a rotating large gear C530, a stator of the electric slip ring C240 is sleeved and fixed outside a gathering tube C420, the stator of the electric slip ring is in conductive connection with one end of a positive lead C231, the other end of the positive lead C231 is in conductive connection with the positive electrode of a direct-current power supply, and therefore current of the direct-current power supply is led into the coil, and the coil is; at this time, the converging tube C420 is not directly assembled with the magnetic separation plate C110 but assembled and fixed with the outer cover C140, and the outer cover C140 is fixed on the magnetic separation plate C110;

the inside of magnetism knockout drum C130, correspond with last scraper blade and lower scraper blade, switch C260 top install and trigger arc board C150, trigger arc board C150 can extrude switch C260's trigger end to make switch C260 cut off the power supply, switch C260 is closed state during initial state. The angle of the trigger arc plate C150 is not more than the corresponding circumferential angle of the cross section of the convergence groove C451 on the end surface of the magnetic sealing disk C540.

When the magnetism adsorption plate got into and assembles groove C451 top, switch C260's trigger end got into and triggers arc board C150 inboard and trigger arc board C150 extrusion switch and make the coil outage, and the magnetism adsorption plate loses magnetism this moment, then the magnetism adsorption plate get into on the scraper blade, scrape down between the scraper blade meeting on its terminal surface the magnetism kind can. After the magnetic adsorption plate rotates away from the upper part of the convergence slot, the power switch rotates out of the trigger arc plate C150, and at the moment, the coil is electrified again.

Preferably, a switch ball capable of rolling in a spherical shape may be installed on the trigger end of the power switch, and the friction force between the power switch and the trigger arc plate C150 may be effectively reduced by the contact, pressing and rolling of the switch ball C261 and the trigger arc plate C150.

Preferably, the separation driving shaft C310 is coaxially assembled with an input shaft of an encoder, so that the rotation angle of the magnetic sealing disk can be estimated by detecting the rotation angle of the separation driving shaft C310 through the encoder in combination with the rotation gear wheel, the rotation pinion gear ratio, and the separation belt gear ratio, which provides a possibility of determining the position of the magnetic adsorption plate.

The controller of the embodiment is used for receiving and sending analysis control instructions, calculating parameters and running programs. An industrial personal computer, a PLC, an MCU, a CPU and the like can be selected.

The invention is not described in detail, but is well known to those skilled in the art.

The foregoing detailed description of the preferred embodiments of the invention has been presented. It should be understood that numerous modifications and variations could be devised by those skilled in the art in light of the present teachings without departing from the inventive concepts. Therefore, the technical solutions available to those skilled in the art through logic analysis, reasoning and limited experiments based on the prior art according to the concept of the present invention should be within the scope of protection defined by the claims.

Claims (10)

1. A purification module, comprising:

the mixing tank is used for mixing the flocculating agent containing the magnetic seeds with the wastewater;

the stirring tank is used for stirring the flocculating agent and the wastewater, and the flocculating agent and the wastewater are actually mixed uniformly;

the sedimentation tank is used for settling the wastewater, so that the wastewater is flocculated under the action of a flocculating agent and magnetic seeds to obtain supernatant, and the purification is finished;

the stirring tank comprises a stirring tank body, a hollow stirring inner cavity is arranged in the stirring tank body, a third mounting disc, a second mounting disc, a stirring wheel, a swinging disc, another stirring wheel and a first mounting disc are sequentially arranged in the stirring inner cavity from bottom to top, the third mounting disc and the bottom of the stirring shaft can be assembled in a circumferential rotating mode, the second mounting disc, the stirring wheel, the swinging disc, the another stirring wheel and the first mounting disc are respectively sleeved outside the stirring cylinder, the second mounting disc, the first mounting disc and the stirring cylinder can be assembled in a circumferential rotating mode, and the two stirring wheels are sleeved outside the stirring cylinder and can be assembled in an axial sliding mode and cannot be assembled in a circumferential rotating mode; the swinging plate is sleeved and fixed outside the stirring cylinder;

the churn is close to first mounting disc department and still is provided with the churn water drainage tank that runs through, and the churn is inside to be hollow stirring inner tube, installs the auger that draws water in the stirring inner tube, draws water the auger outward flange and pastes tight sealed and suit with the inner wall of stirring inner tube and fix on the (mixing) shaft.

2. The purification module of claim 1, wherein the top of the stirring cylinder penetrates through the top of the stirring tank body and is assembled with the stirring tank body in a circumferentially rotatable and axially immovable manner, one end of the stirring cylinder penetrating through the stirring tank body is assembled and fixed with the second stirring gear, the top of the stirring shaft penetrates through the stirring inner cylinder and the stirring support frame and is then assembled and fixed with an output shaft of the stirring motor, the stirring shaft is assembled with the stirring support frame in a circumferentially rotatable and axially immovable manner, and the stirring support frame is fixed on the stirring tank body; the stirring shaft is fixedly sleeved with a first stirring gear, the first stirring gear and the second stirring gear are respectively in meshed transmission with a third stirring gear and a fourth stirring gear, the third stirring gear and the fourth stirring gear are sleeved on a stirring gear shaft, and the stirring gear shaft and the stirring support frame can rotate circumferentially and are in rotating fit.

3. The purification module of claim 1, wherein the stirring wheel is provided with a stirring wheel shaft, the open end of the stirring wheel shaft is provided with a stirring ball in a spherical rolling manner, the stirring ball is attached to the end surface of the swinging disk, and the end surface of the swinging disk is an inclined surface with a vertical potential difference.

4. The purification module of claim 1 or 3, wherein a first stirring spring is installed between the first mounting plate and the stirring wheel close to the first mounting plate, and the first stirring spring is sleeved outside the stirring cylinder and is used for generating an elastic force for the stirring wheel pressed against the first mounting plate to prevent the stirring wheel from moving towards the first mounting plate;

and a second stirring spring is arranged between the second mounting disc and the stirring wheel close to the second mounting disc, and the second stirring spring is sleeved outside the stirring cylinder and used for generating elastic force for blocking the stirring wheel pressed against the second stirring spring from moving to the second mounting disc.

5. The purification module of claim 1, wherein the top of the stirring cavity is communicated with the precipitation cavity through a precipitation water inlet pipe, the precipitation cavity is arranged in a precipitation tank body, the precipitation tank body belongs to the precipitation tank, a turbidity sensor and an electronic liquid level meter are further respectively arranged in the precipitation cavity, and the turbidity sensor is used for detecting the turbidity of water in the precipitation cavity and transmitting signals to the controller; the electronic liquid level meter is used for detecting the water level in the sedimentation inner cavity and inputting signals into the controller; the sediment inner cavity is positioned above the turbidity sensor and is communicated with the bottom of the purification drain pipe, and the purification drain pipe is used for pumping out the clear water after the sediment.

6. The purification module of claim 1, wherein an adsorption bar made of soft iron is installed in the precipitation inner cavity, an electromagnetic coil is sleeved on the adsorption bar, and the electromagnetic coil generates a magnetic field after being electrified, so that the adsorption bar is magnetized; after the sedimentation is finished, the electromagnetic coil is powered off, and the adsorption rod loses magnetism and falls into sludge in the sedimentation inner cavity.

7. The purification module of claim 1, wherein the mixing tank comprises a mixing tank body, the interior of the mixing tank body is a hollow mixing inner cavity, the bottom of the mixing tank body is a mixing conical shell, the bottom of the mixing inner cavity is communicated with one end of a feed pipe, the other end of the feed pipe is communicated with the interior of a suction shell, the interior of the suction shell is hollow and is provided with a first impeller, one end of the interior of the suction shell, which is far away from the end communicated with the feed pipe, is communicated with the bottom of a valve cavity of a valve shell through a drainage pipe, the valve shell is further provided with a conical valve hole and a feed hole, the valve hole is communicated with the valve cavity and the feed hole, the feed hole is communicated with a flocculating agent in the; the valve hole is clamped and hermetically assembled with the valve core, and a valve body pressure spring is arranged between the bottom of the valve core and the bottom surface of the valve cavity; the first impeller is sleeved and fixed on one end of an impeller shaft, the other end of the impeller shaft is installed in the power shell and is assembled and fixed with the second impeller, the second impeller is installed in the power shell, two ends in the power shell are respectively communicated with the mixing inner cavity and the outlet of the water pump, and the inlet of the water pump is communicated with the purification water inlet pipe; the top of the mixing inner cavity is communicated with the bottom of the stirring inner cavity through a mixing pipe.

8. The purification module of claim 7, wherein the mixing cone shell has a diameter that gradually decreases from top to bottom and the bottommost portion of the mixing cone shell is in communication with a mixing drain, the mixing drain being in communication with an inlet of the mixing mud pump; the mixing mud pump is used for pumping the mud in the mixing cavity into the magnetic separator;

the stirring cone shell is arranged at the bottom of a stirring tank body of the stirring tank, the diameter of the stirring cone shell is gradually reduced from top to bottom, the bottom of the stirring cone shell is communicated with a stirring drain pipe, the stirring drain pipe is communicated with an inlet of a stirring slurry pump, and the stirring slurry pump is used for pumping slurry in a stirring inner cavity into a magnetic separator;

the sedimentation tank body bottom of gunbarrel is provided with conical sedimentation awl shell, and the diameter of sedimentation awl shell from top to bottom diminishes gradually and its bottommost and deposit the blow off pipe intercommunication, and the sediment blow off pipe will deposit the mud pump in the inner chamber and pump to the magnetic separator through depositing the slush pump in.

9. A coal mine underground water purification system, which is characterized in that the purification module of any one of claims 1-8 is applied.

10. The coal mine underground water purification system of claim 9, further comprising:

the filter is used for removing floating objects, part of light suspended matters and large-particle solid impurities in the wastewater; most of the waste water enters the main purification module for treatment after passing through the filter, and the water containing a large amount of floaters and suspended matters overflows through the overflow weir and enters the secondary purification module for independent treatment.

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