CN113600326B - Water flow impact type bubble embedded ore crushing processing device - Google Patents

Abstract

The invention discloses a water flow impact type bubble embedded ore crushing processing device which comprises a main body supporting mechanism, a penetrating flow type water circulation impact type ore pre-crushing mechanism, an impact flow cooling type bubble explosion type water source cooling storage mechanism, an electrostatic adsorption type metal retention type dust collecting and filtering mechanism, a pulse injection type anti-blocking type filter screen impurity removing mechanism, a stirring type crushed stone sequencing and blanking mechanism, a linkage type crushed stone dust-free transmission mechanism, a crushed stone collision type extrusion crushing mechanism and a magnetic power type pushed crushed stone cleaning mechanism. The invention belongs to the technical field of ore crushing, and particularly relates to a water flow impact type bubble embedded ore crushing processing device; the invention provides a water flow impact type bubble embedded ore crushing processing device which is integrated with impact force and impact wave, can be used for carrying out double impact on ores, can continuously reduce the hardness of the ores, is convenient for subsequent crushing treatment, and can be used for carrying out maximized purification and discharge on dust-containing gas generated in the transportation and crushing processes of the ores.

Description

Water flow impact type bubble embedded ore crushing processing device

Technical Field

This scheme belongs to ore crushing technical field, specifically indicates a water impact formula bubble embedding type ore crushing processingequipment.

Background

Mine stones are indispensable important materials in the building industry, and in the mining and recycling of the mine stones, the crusher plays a great role and is necessary equipment in mining machinery.

When crushing stone, a crusher is generally used for crushing. However, the existing crusher has low crushing efficiency on stone materials, and the crushing teeth need to be replaced frequently when crushing the stone materials, so that the service life is short; on the other hand, a large amount of dust-like pollutants are inevitably generated when the stone is crushed, and improper treatment of the pollutants not only affects the physical health of operators, but also causes great damage to the surrounding environment.

Disclosure of Invention

In view of the above situation, in order to overcome the defects of the prior art, the present scheme provides a water impact type bubble-embedded ore crushing processing device, which creatively applies the nesting principle (that a certain object passes through a cavity of another object) to the technical field of ore crushing aiming at the problem of short service life of a crushing cutter, and realizes the pre-crushing treatment of ore by using a water impact force and a bubble explosive set breakthrough flow type water circulation impact type ore pre-crushing mechanism and an impact flow cooling type bubble explosive water source cooling storage mechanism, thereby solving the problems that the prior art is difficult to solve that the cutter is not used for crushing ore (the cutter is used for crushing ore, so that the size of crushed ore particles is uniform), but the cutter is not used for crushing ore (the cutter is directly used for crushing ore, so that the service life of the cutter is reduced, thereby greatly improving the cost of ore crushing, and the tool is damaged in the ore crushing process, which seriously affects the ore crushing process and causes the reduction of the use efficiency of the crushing device); the electrostatic adsorption principle and the pulse impurity removal mechanism are creatively applied to the technical field of ore crushing, electrostatic ions are fully retained through the arranged metal net electrostatic adsorption layer, so that the filtration of dust-containing gas is doubly guaranteed, impurities adsorbed on the metal net electrostatic adsorption layer are cleaned through the electromagnetic pulse valve, the filtration of the dust-containing gas is convenient and continuous, and the problem that a large amount of dust pollutants generated by crushed stone cause damage to the surrounding environment is solved; the utility model provides an impact force, shock wave integration set up, carry out dual strike to the ore, can continuously reduce ore hardness, the follow-up broken handle of being convenient for, and can carry out the rivers impact type bubble embedding type ore crushing processingequipment that the maximize purified discharge to the dusty gas that the ore produced in transportation and crushing process.

The technical scheme adopted by the scheme is as follows: the scheme provides a water flow impact type bubble embedded ore crushing processing device which comprises a main body supporting mechanism, a penetrating flow type water circulation impact type ore pre-crushing mechanism, an impact flow cooling type bubble explosion type water source cooling storage mechanism, an electrostatic adsorption type metal retention type dust collecting and filtering mechanism, a pulse injection type anti-blocking filter screen impurity removal mechanism, a stirring type broken stone sequencing and discharging mechanism, a linkage type broken stone dust-free transmission mechanism, a broken stone butt-collision type extrusion crushing mechanism and a magnetic power type push type broken stone cleaning mechanism, wherein the main body supporting mechanism comprises a bottom plate, a supporting frame, a bearing plate, a dust-free crushing box body and a transmission frame, the supporting frame is symmetrically arranged on the upper wall of one end of the bottom plate, the bearing plate is symmetrically arranged on the upper wall of one end of the bottom plate, the dust-free crushing box body is arranged between one side of the bearing plate far from the bottom plate, and the dust-free crushing box body is a cavity with one end open, the transmission frame is arranged on the upper wall of the support frame, one side of the transmission frame, which is far away from the support frame, penetrates through an opening of the dust-free crushing box body and is arranged on the inner wall of one side of the dust-free crushing box body, the through-flow type water circulation impact type ore pre-crushing mechanism is arranged at one end, which is close to the support frame, of the dust-free crushing box body, the impact flow cooling type bubble explosion type water source cooling storage mechanism is arranged on the upper wall of the bottom plate, the electrostatic adsorption type metal retention type dust collecting and filtering mechanism is arranged on the side wall of the dust-free crushing box body, the pulse jet type anti-blocking filter screen impurity removing mechanism is arranged on the side wall of the electrostatic adsorption type metal retention type dust collecting and filtering mechanism, the stirring type crushed stone sequencing and blanking mechanism is arranged at one end, which is close to the support frame, the linkage type dust-free crushed stone transmission mechanism is arranged on the inner wall of the transmission frame, the crushed stone counter-impact type extrusion and crushing mechanism is arranged on the dust-free crushing box body below one end, which is far away from the support frame, the magnetic power type pushing type stone crushing cleaning mechanism is arranged at the bottom of the dust-free crushing box body.

As a further optimization of the scheme, the through-flow type water circulation impact type ore pre-crushing mechanism comprises a high-pressure water pump, a water pumping pipe, a water outlet pipeline, a flow dividing pipeline, a supporting plate, a connecting pipeline, an annular impact pipeline, an impact nozzle, a water return port and a filter screen, wherein the high-pressure water pump is arranged on the upper wall of a bottom plate on one side of a dust-free crushing box body, the water pumping pipe is arranged at the power input end of the high-pressure water pump, the water outlet pipeline is arranged at the power output end of the high-pressure water pump, the supporting plate is symmetrically arranged on one side, close to the high-pressure water pump, of the dust-free crushing box body, the flow dividing pipeline is arranged between the supporting plates, one side, far away from the high-pressure water pump, of the water outlet pipeline is communicated with the flow dividing pipeline, a plurality of groups of the annular impact pipelines are arranged on the upper wall of a transmission frame, the connecting pipeline penetrates through the side wall of the dust-free crushing box body and is communicated with the annular impact pipeline, a plurality of the groups of the impact nozzle are communicated with the annular impact pipeline, strike the shower nozzle and set up with transmission frame relatively, the dustless broken bottom half of the case portion of striking shower nozzle below is located to the return water mouth, return water mouth inner wall is located to the filter screen, and the water pump passes through the drinking-water pipe and extracts the water source, and in the water source entered into the reposition of redundant personnel pipeline through outlet conduit, the reposition of redundant personnel pipeline shunts the water source, and in the connecting tube shunted the connecting tube, the connecting tube carried the water source annular impact pipeline, the annular impact pipeline was strikeed the rubble through the blow-out of impact nozzle with the water source, and spun moisture is retrieved through the return water mouth after the filter screen filters.

Preferably, the electrostatic adsorption type metal retention type dust collecting and filtering mechanism comprises a dust collecting box body, an exhaust port, an exhaust fan, a metal net electrostatic adsorption layer, a wide-mouth dust collecting head, a dust collecting pipeline, a conveying pipeline, a fixing clamp and an electrostatic generator, wherein the dust collecting box body is arranged on one side of the dust-free crushing box body, which is far away from the shunt pipeline, the exhaust port is arranged on the upper wall of the dust collecting box body, the exhaust fan is arranged in the exhaust port, the metal net electrostatic adsorption layer is arranged on the inner wall of the dust collecting box body, the dust collecting pipeline is arranged above the dust-free crushing box body, two ends of the dust collecting pipeline are arranged in the dust-free crushing box body in a penetrating manner, the wide-mouth dust collecting head is symmetrically arranged at two ends of the dust collecting pipeline, the wide-mouth dust collecting head is arranged in the dust-free crushing box body, the wide-mouth dust collecting head is communicated with the dust collecting pipeline, the conveying pipeline is communicated between the dust collecting pipeline and the dust collecting box body, and the fixing clamp is arranged between the dust collecting box body and the conveying pipeline, the utility model discloses a dust collection box, including dust collection box body, dust collection pipeline, static generator, dust exhaust fan, dust collection box body, dust exhaust fan, dust exhaust.

Specifically, the impact flow cooling type bubble explosion water source cooling storage mechanism comprises a water storage box body, an ultrasonic oscillator, a vortex tube, an air compressor, a compressed gas discharge pipeline, a compressed gas inlet pipeline, an air conditioning pipeline, a cooling copper plate and a pipeline clamp, wherein the water storage box body is arranged on the upper wall of a bottom plate below a water return port, the water storage box body is a cavity with an upper end opened, one side of the water suction pipe far away from a high-pressure water pump is communicated with the water storage box body, the ultrasonic oscillator is arranged on the side wall of the water storage box body, the power end of the ultrasonic oscillator is arranged inside the water storage box body in a penetrating manner, the vortex tube is arranged on one side of a dust collection box body far away from a fixing clamp, the air compressor is arranged on the side wall of a dust-free crushing box body on one side of the vortex tube, the compressed gas discharge pipeline is arranged on the power output end of the air compressor, the compressed gas inlet pipeline is communicated between the compressed gas discharge pipeline and the power input end of the vortex tube, the utility model discloses a water storage tank, including the water storage tank, the water storage tank is located to the air conditioning pipeline intercommunication, air compressor carries the compressed gas who produces in the compressed gas inlet line through compressed gas discharge pipeline, and the compressed gas who produces in the compressed gas inlet line, and the vortex tube is carried to the compressed gas in the compressed gas inlet line, and the vortex tube is spouted the air conditioning pipeline with the air conditioning that produces to the cooling copper, and under the effect of impulse flow effect, the cooling copper cools off rapidly, and the temperature of the internal moisture of storage tank is absorbed to the cooling copper, makes the internal moisture of storage tank fully cool off, and the ultrasonic oscillator vibrates the internal moisture of storage tank through the power end, produces a large amount of small cavitation bubbles in the internal moisture of storage tank under ultrasonic oscillator's effect.

Wherein, pulse injection formula prevents stifled type filter screen edulcoration mechanism includes electromagnetic pulse valve, injection pipeline, jet, pulse admission line and control valve, the dust collection box lateral wall of vortex tube top is located to the electromagnetic pulse valve, the dust collection box inner wall of metal mesh electrostatic adsorption layer top is located to the injection pipeline, and the injection pipeline runs through the dust collection box inner wall and locates the jet-propelled end of electromagnetic pulse valve, the injection pipeline diapire is located to the jet, the pulse admission line intercommunication is located between compressed gas discharge pipe and the electromagnetic pulse valve inlet end, the control valve is located on the pulse admission line, and compressed gas passes through the pulse admission line and enters into the electromagnetic pulse valve in, and the electromagnetic pulse valve passes through the jet and clears up the adsorbed impurity of gaseous blowout on the metal mesh electrostatic adsorption layer.

Preferably, the stirring type crushed stone sequencing and blanking mechanism comprises a blanking box body, a blanking motor, a stirring shaft, a stirring roller, a driving gear and a fixed bracket, the fixed bracket is arranged on the upper wall of one end of the transmission frame far away from the dust-free crushing box body, the blanking box body is arranged on one side of the fixed bracket far away from the transmission frame and is arranged in a vertically through way, the stirring shaft is rotationally arranged on the inner wall of the blanking box body, the stirring roller is arranged outside the impact spray head, the blanking motor is arranged on the side wall of the blanking box body, the stirring shaft penetrates through the blanking box body and is arranged at the power output end of the blanking motor, the one end that the unloading motor was kept away from to the (mixing) shaft runs through the unloading box, the one end that the unloading motor was kept away from to the (mixing) shaft is located to the driving gear, and the unloading box is located to the driving gear outside, and in the ore was put into the unloading box, the unloading motor drove the (mixing) shaft and rotates, and the (mixing) shaft drove the stirring roller and stirs the unloading to the ore.

Further, dustless transport mechanism of coordinated type rubble includes conveying roller, conveyer belt, driven gear and toothed belt, conveying roller multiunit rotates and locates the transmission frame inner wall, the conveying roller outside is located to the conveying roller, the conveyer belt is around locating on the conveying roller, the transmission roller that the transmission frame is close to driving gear one end runs through the transmission frame inner wall, driven gear locates the one end that the transmission roller runs through the transmission frame, the toothed belt is around locating between driving gear and the driven gear, toothed belt respectively with driving gear and driven gear meshing, the driving gear rotates and drives driven gear through the toothed belt and rotate, driven gear drives the conveying roller through the conveying roller and rotates, the conveying roller drives the conveyer belt and conveys the ore.

Still further, the broken stone colliding type extruding and crushing mechanism comprises a crushing motor, a crushing shaft, a crushing roller, a linkage gear, an auxiliary gear, a feed opening and a storage box, wherein the crushing motor is arranged on the side wall of one end, away from the support frame, of the dust-free crushing box body, the crushing shaft is symmetrically arranged on the inner wall of one end, away from the feed box body, of the dust-free crushing box body, the crushing shaft is rotatably arranged on the inner wall of the dust-free crushing box body, the crushing roller is arranged on the outer side of the crushing shaft, one end, away from the crushing motor, of the crushing shaft penetrates through the inner wall of the dust-free crushing box body and is arranged outside the dust-free crushing box body, the linkage gear is arranged at one end, away from the crushing motor, of the crushing shaft, the auxiliary gear is arranged on the crushing shaft on one side of the linkage gear, the linkage gear is meshed with the auxiliary gear, the feed opening is arranged at the bottom of the dust-free crushing box body below the crushing roller, and the storage box is arranged on the upper wall of the bottom plate below the feed opening, the storage case is upper end open-ended cavity, and crushing motor drives broken axle and rotates, and broken axle drives broken roller and rotates and carry out the extrusion breakage to the ore, and the ore after the breakage is saved in dropping to the storage case through the feed opening.

Furthermore, the magnetic power type pushing type gravel cleaning mechanism comprises a sliding groove, a sliding block, a cleaning plate, a cleaning electromagnet and a fixed electromagnet, the sliding grooves are symmetrically arranged on the inner walls of the two sides of the bottom of the dust-free crushing box body, the sliding grooves are arranged in a cavity with one open end, the slide blocks are arranged in the slide grooves in a sliding mode, the cleaning plate is arranged between the slide blocks, the cleaning electromagnet is arranged on one side, far away from the feed opening, of the cleaning plate, fixed electro-magnet is located dustless broken box and is kept away from the one end diapire of feed opening, and clearance electro-magnet and fixed electro-magnet set up relatively, and clearance electro-magnet and fixed electro-magnet are circular telegram respectively, and clearance electro-magnet and fixed electro-magnet homopolar setting, the clearance electro-magnet promote the clearance electro-magnet through the repulsion and remove, and the clearance electro-magnet drives the clearance board and removes, and the clearance board passes through the slider and slides along the sliding tray, and the broken stone that the clearance board drove dustless broken bottom of the box is inside the dustless broken box of feed opening discharge.

The side wall of the dust-free crushing box body is provided with a controller, and the controller is respectively electrically connected with the high-pressure water pump, the ultrasonic oscillator, the air compressor, the air exhaust fan, the electrostatic generator, the electromagnetic pulse valve, the blanking motor, the crushing motor, the cleaning electromagnet and the fixed electromagnet.

The beneficial effect who adopts above-mentioned structure this scheme to gain is as follows: according to the water flow impact type bubble embedded ore crushing processing device, the impact on the surface of ore is realized through the through flow type water circulation impact type ore pre-crushing mechanism arranged according to the pre-acting principle, the hardness of the ore is damaged to a certain degree, and the service life of the crushing cutter for crushing the ore is prolonged; the impact flow cooling type bubble explosion type water source cooling storage mechanism which is arranged by adopting an explosion generated impact wave effect realizes the reduction of the hardness of ores, bubbles pretreat and crush the ores along with impact water flow, the efficiency of water flow impact is greatly increased by the bubbles, the method effectively improves the crushing efficiency of the ores under the perfect combination of water flow impact and the bubbles, under the condition of no intervention of large-scale refrigeration equipment, a vortex tube arranged by adopting the impact flow effect impacts a cooling copper plate to continuously and rapidly cool the water temperature in a water storage tank body, an ultrasonic oscillator vibrates the water in the water storage tank body through a power end to generate a large amount of bubbles, a high-pressure water pump extracts the water source with the bubbles in the water storage tank body through a water pumping pipe, the water source enters a diversion pipeline through a water outlet pipeline, and the diversion pipeline diverts the water source, a water source is shunted into a connecting pipeline, the connecting pipeline conveys the water source into an annular impact pipeline, the annular impact pipeline sprays the water source out of an impact spray head to impact the gravel, impact waves generated by explosion of a large number of bubbles impact the surface of ore, and sprayed water is filtered by a filter screen and then falls into a water storage tank body through a water return port to be recycled; the method is characterized in that the dust-containing gas is filtered and discharged under the condition that large-scale dust removing equipment is not involved, the wide-mouth dust collection head sucks the dust-containing gas in a dust-free crushing box body into a dust collection pipeline, the dust collection pipeline conveys the dust-containing gas into a dust collection box body through a conveying pipeline, a static generator conveys generated static ions into the dust collection box body through a power end, the static ions are adsorbed on a metal mesh static adsorption layer, and the dust-containing gas is purified by the metal mesh static adsorption layer and then discharged through an exhaust port; the pulse jet type anti-blocking filter screen impurity removing mechanism achieving the cleaning of impurities on the metal mesh electrostatic adsorption layer through pulse dust removal setting avoids manual removal of replacement of a filtering device, compressed gas enters the electromagnetic pulse valve through the pulse air inlet pipeline, and the electromagnetic pulse valve cleans impurities adsorbed on the metal mesh electrostatic adsorption layer through gas jet by the jet orifice.

Drawings

Fig. 1 is a schematic structural diagram of a water-flow impact type bubble-embedded ore crushing processing device according to the present embodiment;

fig. 2 is a perspective view of a water-impact bubble-embedded ore crushing processing device according to the present embodiment;

fig. 3 is a front view of a water-impact bubble-embedded ore crushing processing device according to the present embodiment;

fig. 4 is a rear view of a water-impact bubble-embedded ore crushing processing device according to the present embodiment;

fig. 5 is a left side view of a water-impact bubble-embedded ore crushing processing device according to the present embodiment;

fig. 6 is a right side view of a water-impact bubble-embedded ore crushing processing device according to the present embodiment;

fig. 7 is a plan view of a water-impact bubble-embedded ore crushing processing device according to the present embodiment;

FIG. 8 is a partial sectional view A-A of FIG. 7;

FIG. 9 is a sectional view of portion B-B of FIG. 4;

FIG. 10 is a partial cross-sectional view of C-C of FIG. 3

FIG. 11 is a circuit diagram of a water-impact type bubble-embedded ore crushing processing device controller according to the present invention

Fig. 12 is a schematic block diagram of a water-flow impact type bubble-embedded ore crushing processing device according to the present embodiment.

Wherein, 1, a main body supporting mechanism, 2, a bottom plate, 3, a supporting frame, 4, a bearing plate, 5, a through-flow type water circulation impact type ore pre-crushing mechanism, 6, a high-pressure water pump, 7, a dust-free crushing box body, 8, a controller, 9, a water pumping pipe, 10, a water outlet pipeline, 11, a flow dividing pipeline, 12, a supporting plate, 13, a connecting pipeline, 14, an annular impact pipeline, 15, an impact spray head, 16, a water return port, 17, a filter screen, 18, an impact flow cooling type bubble explosion type water source cooling storage mechanism, 19, a water storage box body, 20, an ultrasonic oscillator, 21, a vortex pipe, 22, an air compressor, 23, a compressed air discharge pipeline, 24, a compressed air inlet pipeline, 25, a cold air pipeline, 26, a cooling copper plate, 27, a pipeline clamp, 28, an electrostatic adsorption type metal retention type dust collecting and filtering mechanism, 29, a dust collecting box body, 30 and an exhaust port, 31. an air suction fan, 32, a metal mesh electrostatic adsorption layer, 33, a wide-mouth dust suction head, 34, a dust collection pipeline, 35, a conveying pipeline, 36, a fixing clamp, 37, a pulse jet type anti-blocking filter screen impurity removal mechanism, 38, an electromagnetic pulse valve, 39, a jet pipeline, 40, a jet orifice, 41, a pulse air inlet pipeline, 42, a stirring type crushed stone sequencing and blanking mechanism, 43, a blanking box body, 44, a blanking motor, 45, a stirring shaft, 46, a stirring roller, 47, a driving gear, 48, a fixing support, 49, a linkage type crushed stone dust-free conveying mechanism, 50, a conveying frame, 51, a conveying roller shaft, 52, a conveying roller, 53, a conveying belt, 54, a driven gear, 55, a gear belt, 56, a crushed stone collision type extrusion crushing mechanism, 57, a crushing motor, 58, a crushing shaft, 59, a crushing roller, 60, a linkage gear, 61, an auxiliary gear, 62 and a magnetic power type pushing type crushed stone cleaning mechanism, 63. the device comprises a sliding groove, 64, a sliding block, 65, a cleaning plate, 66, a cleaning electromagnet, 67, a fixed electromagnet, 68, an electrostatic generator, 69, a storage tank, 70, a feed opening, 71 and a control valve.

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

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments; all other embodiments obtained by a person of ordinary skill in the art based on the embodiments in the present disclosure without any creative effort belong to the protection scope of the present disclosure.

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

As shown in fig. 1-2, the water impact type bubble-embedded ore crushing processing device provided by the present scheme comprises a main body supporting mechanism 1, a breakthrough flow type water circulation impact type ore pre-crushing mechanism 5, an impact flow cooling type bubble explosion water source cooling storage mechanism 18, an electrostatic adsorption type metal retention type dust collecting and filtering mechanism 28, a pulse jet type anti-blocking type filter screen impurity removing mechanism 37, a stirring type broken stone sorting and blanking mechanism 42, a linkage type broken stone dust-free transmission mechanism 49, a broken stone collision type extrusion crushing mechanism 56 and a magnetic power type broken stone cleaning mechanism 62, wherein the main body supporting mechanism 1 comprises a bottom plate 2, a supporting frame 3, a bearing plate 4, a dust-free crushing box body 7 and a transmission frame 50, the supporting frame 3 is symmetrically arranged on the upper wall of one end of the bottom plate 2, the bearing plate 4 is symmetrically arranged on the upper wall of one end of the bottom plate 2 far away from the supporting frame 3, the dust-free crushing box body 7 is arranged between one sides of the bearing plates 4 far away from the bottom plate 2, the dust-free crushing box body 7 is a cavity with one open end, the transmission frame 50 is arranged on the upper wall of the support frame 3, one side of the transmission frame 50 far away from the support frame 3 penetrates through the opening of the dust-free crushing box body 7 and is arranged on the inner wall of one side of the dust-free crushing box body 7, the through-flow type water circulation impact type ore pre-crushing mechanism 5 is arranged at one end of the dust-free crushing box body 7 close to the support frame 3, the impact flow cooling type bubble explosion type water source cooling storage mechanism 18 is arranged on the upper wall of the bottom plate 2, the electrostatic adsorption type metal retention type dust collecting and filtering mechanism 28 is arranged on the side wall of the dust-free crushing box body 7, the pulse jet type anti-blocking filter screen impurity removing mechanism 37 is arranged on the side wall of the electrostatic adsorption type metal retention type dust collecting and filtering mechanism 28, and the stirring type crushed stone sequencing and blanking mechanism 42 is arranged at one end of the transmission frame 50 close to the support frame 3, the linkage type gravel dust-free conveying mechanism 49 is arranged on the inner wall of the conveying frame 50, the gravel collision type extrusion crushing mechanism 56 is arranged on the dust-free crushing box body 7 below one end, far away from the supporting frame 3, of the conveying frame 50, and the magnetomotive type push type gravel cleaning mechanism 62 is arranged at the bottom of the dust-free crushing box body 7.

As shown in fig. 4 and 10, the through-flow type water circulation impact type ore pre-crushing mechanism 5 comprises a high-pressure water pump 6, a water pumping pipe 9, a water outlet pipeline 10, a diversion pipeline 11, a support plate 12, a connecting pipeline 13, an annular impact pipeline 14, an impact nozzle 15, a water return port 16 and a filter screen 17, wherein the high-pressure water pump 6 is arranged on the upper wall of a bottom plate 2 on one side of a dust-free crushing box body 7, the water pumping pipe 9 is arranged at the power input end of the high-pressure water pump 6, the water outlet pipeline 10 is arranged at the power output end of the high-pressure water pump 6, the support plate 12 is symmetrically arranged on one side of the dust-free crushing box body 7 close to the high-pressure water pump 6, the diversion pipeline 11 is arranged between the support plates 12, one side of the water outlet pipeline 10 far away from the high-pressure water pump 6 is communicated with the diversion pipeline 11, a plurality of the annular impact pipelines 14 are arranged on the upper wall of a transmission frame 50, and the connecting pipeline 13 is communicated with the annular impact pipeline 14 through the side wall of the dust-free crushing box body 7, impact shower nozzle 15 multiunit intercommunication is located annular impact pipeline 14, impact shower nozzle 15 sets up with transmission frame 50 relatively, return water mouth 16 is located the dustless broken box 7 bottom of impact shower nozzle 15 below, return water mouth 16 inner wall is located to filter screen 17, high pressure water pump 6 passes through drinking-water pipe 9 and extracts the water source, the water source enters into in the reposition of redundant personnel pipeline 11 through outlet conduit 10, reposition of redundant personnel pipeline 11 shunts the water source, the water source shunts in connecting tube 13, connecting tube 13 carries the water source in annular impact pipeline 14, annular impact pipeline 14 is strikeed the rubble through the 15 blowout of impact shower nozzle with the water source, spun moisture retrieves through return water mouth 16 after filter screen 17 filters.

As shown in fig. 5-8, the electrostatic adsorption type metal-retaining dust collecting and filtering mechanism 28 includes a dust collecting box 29, an exhaust port 30, an air extracting fan 31, a metal mesh electrostatic adsorption layer 32, a wide-mouth dust absorbing head 33, a dust collecting pipeline 34, a conveying pipeline 35, a fixing clamp 36 and an electrostatic generator 68, wherein the dust collecting box 29 is disposed on one side of the dust-free crushing box 7 away from the shunt pipeline 11, the exhaust port 30 is disposed on the upper wall of the dust collecting box 29, the air extracting fan 31 is disposed in the exhaust port 30, the metal mesh electrostatic adsorption layer 32 is disposed on the inner wall of the dust collecting box 29, the dust collecting pipeline 34 is disposed above the dust-free crushing box 7, two ends of the dust collecting pipeline 34 are disposed inside the dust-free crushing box 7, the wide-mouth dust absorbing heads 33 are symmetrically disposed at two ends of the dust collecting pipeline 34, the wide-mouth dust absorbing head 33 is disposed inside the dust-free crushing box 7, the wide-mouth dust absorbing head 33 is communicated with the dust collecting pipeline 34, the conveying pipeline 35 is communicated between the dust collecting pipeline 34 and the dust collecting box 29, the fixing clamp 36 is arranged between the dust collection box body 29 and the conveying pipeline 35, the electrostatic generator 68 is arranged on one side, far away from the dust-free crushing box body 7, of the dust collection box body 29, the power end of the electrostatic generator 68 penetrates through the interior of the dust collection box body 29, the suction fan 31 rotates to suck dust-containing gas in the dust-free crushing box body 7 into the dust collection pipeline 34 through the wide-mouth dust suction head 33, the dust collection pipeline 34 conveys the dust-containing gas into the dust collection box body 29 through the conveying pipeline 35, the electrostatic generator 68 conveys generated electrostatic ions into the dust collection box body 29 through the power end, the electrostatic ions are adsorbed on the metal mesh electrostatic adsorption layer 32, and the dust-containing gas is purified through the metal mesh electrostatic adsorption layer 32 and then is discharged through the exhaust port 30.

As shown in fig. 2, 3 and 10, the impact flow cooling type bubble explosion type water source temperature reduction storage mechanism 18 comprises a water storage tank 19, an ultrasonic oscillator 20, a vortex tube 21, an air compressor 22, a compressed gas discharge pipeline 23, a compressed air inlet pipeline 24, a cold air pipeline 25, a cooling copper plate 26 and a pipeline clamp 27, wherein the water storage tank 19 is arranged on the upper wall of the bottom plate 2 below the water return port 16, the water storage tank 19 is a cavity with an open upper end, one side of the water pumping pipe 9 away from the high pressure water pump 6 is communicated with the water storage tank 19, the ultrasonic oscillator 20 is arranged on the side wall of the water storage tank 19, the power end of the ultrasonic oscillator 20 penetrates through the water storage tank 19, the vortex tube 21 is arranged on one side of the dust collection tank 29 away from the fixing clamp 36, the air compressor 22 is arranged on the side wall of the dust-free crushing tank 7 on one side of the vortex tube 21, the compressed gas discharge pipeline 23 is arranged on the power output end of the air compressor 22, the compressed air inlet pipeline 24 is communicated between the compressed air outlet pipeline 23 and the power input end of the vortex tube 21, the cold air pipeline 25 is communicated between the water storage box body 19 and the power output end of the vortex tube 21, the pipeline clamp 27 is arranged between the side wall of the dust collection box body 29 and the cold air pipeline 25, the cooling copper plate 26 is arranged at the bottom wall of one end of the water storage box body 19 close to the cold air pipeline 25, the air compressor 22 delivers the generated compressed air into the compressed air inlet pipeline 24 through the compressed air outlet pipeline 23, the compressed air in the compressed air inlet pipeline 24 is delivered into the vortex tube 21, the vortex tube 21 sprays the generated cold air to the cooling copper plate 26 through the cold air pipeline 25, under the effect of an impact flow effect, the cooling copper plate 26 is rapidly cooled, the cooling copper plate 26 absorbs the temperature of the water in the water storage box body 19, so that the water in the water storage box body 19 is fully cooled, the ultrasonic oscillator 20 vibrates the water in the water storage box body 19 through the power end, a large amount of micro cavitation bubbles are generated in the water storage tank body 19 under the action of the ultrasonic oscillator 20.

As shown in fig. 7 and 10, the pulse jet type anti-clogging filter screen impurity removing mechanism 37 includes an electromagnetic pulse valve 38 and a jet pipe 39, the device comprises a jet orifice 40, a pulse air inlet pipeline 41 and a control valve 71, wherein the electromagnetic pulse valve 38 is arranged on the side wall of the dust collection box body 29 above the vortex tube 21, the jet pipeline 39 is arranged on the inner wall of the dust collection box body 29 above the metal net electrostatic adsorption layer 32, the jet pipeline 39 penetrates through the inner wall of the dust collection box body 29 and is arranged at the air injection end of the electromagnetic pulse valve 38, the jet orifice 40 is arranged on the bottom wall of the jet pipeline 39, the pulse air inlet pipeline 41 is communicated between the compressed gas discharge pipeline 23 and the air inlet end of the electromagnetic pulse valve 38, the control valve 71 is arranged on the pulse air inlet pipeline 41, compressed gas enters the electromagnetic pulse valve 38 through the pulse air inlet pipeline 41, and the electromagnetic pulse valve 38 ejects gas through the jet orifice 40 to clean impurities adsorbed on the metal net electrostatic adsorption layer 32.

As shown in fig. 2, fig. 3, fig. 4 and fig. 8, the stirring type crushed stone sequencing and discharging mechanism 42 comprises a discharging box body 43, a discharging motor 44, a stirring shaft 45, a stirring roller 46, a driving gear 47 and a fixed bracket 48, wherein the fixed bracket 48 is arranged on the upper wall of one end of a transmission frame 50 far away from the dust-free crushing box body 7, the discharging box body 43 is arranged on one side of the fixed bracket 48 far away from the transmission frame 50, the discharging box body 43 is arranged in a vertically through manner, the stirring shaft 45 is rotatably arranged on the inner wall of the discharging box body 43, the stirring roller 46 is arranged outside the impact nozzle 15, the discharging motor 44 is arranged on the side wall of the discharging box body 43, the stirring shaft 45 penetrates through the discharging box body 43 and is arranged at the power output end of the discharging motor 44, one end of the stirring shaft 45 far away from the discharging motor 44 penetrates through the discharging box body 43, the driving gear 47 is arranged outside the discharging box body 43, and ores are put into the discharging box body 43, the blanking motor 44 drives the stirring shaft 45 to rotate, and the stirring shaft 45 drives the stirring roller 46 to stir and blank the ore.

As shown in fig. 3 and 8, the linked gravel dust-free conveying mechanism 49 comprises a conveying roller shaft 51 and a conveying roller 52, conveyer belt 53, driven gear 54 and gear area 55, the transmission roller 51 multiunit is rotated and is located transmission frame 50 inner wall, the transmission roller 52 is located the transmission roller 51 outside, conveyer belt 53 is around locating on transmission roller 52, transmission frame 50 is close to the transmission roller 51 of driving gear 47 one end and runs through transmission frame 50 inner wall, driven gear 54 is located the one end that transmission roller 51 runs through transmission frame 50, gear area 55 is around locating between driving gear 47 and driven gear 54, gear area 55 meshes with driving gear 47 and driven gear 54 respectively, driving gear 47 rotates and drives driven gear 54 through gear area 55 and rotates, driven gear 54 drives transmission roller 52 through transmission roller 51 and rotates, transmission roller 52 drives conveyer belt 53 and conveys the ore.

As shown in fig. 8-9, the crushing mechanism 56 includes a crushing motor 57, a crushing shaft 58, a crushing roller 59, a linkage gear 60, an auxiliary gear 61, a material outlet 70 and a material storage box 69, the crushing motor 57 is disposed on a side wall of one end of the dustless crushing box 7 far from the support frame 3, the crushing shaft 58 is symmetrically disposed on an inner wall of one end of the dustless crushing box 7 far from the material outlet 43, the crushing shaft 58 is rotatably disposed on an inner wall of the dustless crushing box 7, the crushing roller 59 is disposed on an outer side of the crushing shaft 58, one end of the crushing shaft 58 far from the crushing motor 57 penetrates through the inner wall of the dustless crushing box 7 and is disposed outside the dustless crushing box 7, the linkage gear 60 is disposed on one end of the crushing shaft 58 far from the crushing motor 57, the auxiliary gear 61 is disposed on the crushing shaft 58 on one side of the linkage gear 60, the linkage gear 60 is engaged with the auxiliary gear 61, the material outlet 70 is disposed at the bottom of the dustless crushing box 7 below the crushing roller 59, storage case 69 locates the bottom plate 2 upper wall of feed opening 70 below, and storage case 69 is upper end open-ended cavity, and crushing motor 57 drives crushing axle 58 and rotates, and crushing axle 58 drives crushing roller 59 and rotates and carry out the extrusion breakage to the ore, and the ore after the breakage falls to storage case 69 through feed opening 70 and stores.

As shown in fig. 8 and 10, the magnetomotive push-type gravel cleaning mechanism 62 comprises a sliding groove 63, a sliding block 64, a cleaning plate 65, a cleaning electromagnet 66 and a fixed electromagnet 67, wherein the sliding groove 63 is symmetrically arranged on the inner walls of two sides of the bottom of the dust-free crushing box body 7, the sliding groove 63 is a cavity with an opening at one end, the sliding block 64 is slidably arranged in the sliding groove 63, the cleaning plate 65 is arranged between the sliding blocks 64, the cleaning electromagnet 66 is arranged on one side of the cleaning plate 65 away from the feeding opening 70, the fixed electromagnet 67 is arranged on the bottom wall of the dust-free crushing box body 7 away from the feeding opening 70, the cleaning electromagnet 66 and the fixed electromagnet 67 are oppositely arranged, the cleaning electromagnet 66 and the fixed electromagnet 67 are respectively electrified, the cleaning electromagnet 66 and the fixed electromagnet 67 are arranged in the same polarity, the cleaning electromagnet 66 pushes the cleaning electromagnet 66 to move through a repulsive force, the cleaning electromagnet 66 drives the cleaning plate 65 to move, the cleaning plate 65 slides along the sliding groove 63 through the sliding block 64, the cleaning plate 65 drives the crushed stone at the bottom of the dust-free crushing box 7 to be discharged out of the dust-free crushing box 7 from the feed opening 70.

As shown in fig. 3, 11 and 12, the controller 8 is disposed on the sidewall of the dust-free crushing box 7, and the controller 8 is electrically connected to the high-pressure water pump 6, the ultrasonic oscillator 20, the air compressor 22, the suction fan 31, the electrostatic generator 68, the electromagnetic pulse valve 38, the blanking motor 44, the crushing motor 57, the cleaning electromagnet 66 and the fixing electromagnet 67, respectively.

When the ore crusher is used specifically, in the first embodiment, an ore is put into the blanking box 43, the controller 8 controls the blanking motor 44 to start, the blanking motor 44 drives the stirring shaft 45 to rotate, the stirring shaft 45 drives the stirring roller 46 to stir and blank the ore, the ore in the blanking box 43 falls onto the conveyor belt 53, the driving gear 47 rotates to drive the driven gear 54 to rotate through the gear belt 55, the driven gear 54 drives the conveying roller 52 to rotate through the conveying roller shaft 51, the conveying roller 52 drives the conveyor belt 53 to convey the ore to the inside of the dust-free crushing box 7, the controller 8 controls the air compressor 22 to start, the air compressor 22 compresses outside air, the compressed gas output end of the air compressor 22 is communicated with the compressed gas discharge pipeline 23, the air compressor 22 conveys the generated compressed gas into the compressed gas inlet pipeline 24 through the compressed gas discharge pipeline 23, compressed gas in a compressed gas inlet pipeline 24 is conveyed into a vortex tube 21 through a compressed gas inlet of the vortex tube 21, the vortex tube 21 discharges the generated cold gas from a cold gas outlet of the vortex tube 21, the cold gas is sprayed to a cooling copper plate 26 through a cold gas pipeline 25, the cooling copper plate 26 is rapidly cooled under the action of an impact flow effect, the cooling copper plate 26 absorbs the temperature of water in a water storage tank body 19 to fully cool the water in the water storage tank body 19, a controller 8 controls an ultrasonic oscillator 20 to be started, the ultrasonic oscillator 20 vibrates the water in the water storage tank body 19 through a power end, a large amount of tiny cavitation bubbles are generated in the cooling water in the water storage tank body 19 under the action of the ultrasonic oscillator 20, the controller 8 controls a high-pressure water pump 6 to be started, the high-pressure water pump 6 pumps a water source containing the bubbles through a water pumping pipe 9, and the water source enters a diversion pipeline 11 through a water outlet pipeline 10, the water source is shunted by the shunt pipe 11, the shunted water source enters the connecting pipe 13, the connecting pipe 13 conveys the water source into the annular impact pipe 14, the annular impact pipe 14 sprays the water source containing bubbles through the impact spray head 15 to impact broken stone, impact waves generated by bubble explosion impact ores again, sprayed water falls into the bottom of the dust-free crushing box 7, the water at the bottom of the dust-free crushing box 7 is filtered by the filter screen 17 and then falls into the water storage tank 19 through the return port 16 for recycling, the impacted ores are conveyed onto the crushing roller 59 along with the conveyor belt 53, the controller 8 controls the crushing motor 57 to be started, the crushing motor 57 drives the crushing shaft 58 to rotate, the crushing shaft 58 drives the crushing roller 59 to rotate, the crushing shaft 58 drives the auxiliary gear 61 to rotate through the linkage gear 60, the auxiliary gear 61 drives the crushing roller 59 on one side of the crushing motor 57 to rotate, the ore is extruded and crushed under the action force of the crushing roller 59, and the crushed ore falls into a storage box 69 through a feed opening 70 for storage; in the second embodiment, dust generated in ore transportation and crushing is collected and filtered, the controller 8 controls the suction fan 31 to start, the suction fan 31 rotates to suck dust-containing gas in the dust-free crushing box 7 into the dust collecting pipeline 34 through the wide-mouth dust suction head 33, the dust collecting pipeline 34 conveys the dust-containing gas into the dust collecting box 29 through the conveying pipeline 35, the controller 8 controls the electrostatic generator 68 to start, the electrostatic generator 68 conveys generated electrostatic ions into the dust collecting box 29 through the power end, the electrostatic ions are adsorbed on the metal mesh electrostatic adsorption layer 32, the dust-containing gas is filtered through the metal mesh electrostatic adsorption layer 32, the electrostatic ions attached on the metal mesh electrostatic adsorption layer 32 adsorb the dust, and the purified gas is discharged through the exhaust port 30; in the third embodiment, the impurities blocked on the metal mesh electrostatic adsorption layer 32 are cleaned, the controller 8 controls the electromagnetic pulse valve 38 to start, the control valve 71 is opened to enable compressed gas to enter the electromagnetic pulse valve 38, the compressed gas enters the electromagnetic pulse valve 38 through the pulse gas inlet pipeline 41, and the electromagnetic pulse valve 38 ejects the gas through the ejection opening 40 to flush the impurities adsorbed on the metal mesh electrostatic adsorption layer 32 to the bottom of the dust collection box body 29, so that the metal mesh electrostatic adsorption layer 32 is prevented from being blocked.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present solution have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the solution, the scope of which is defined in the appended claims and their equivalents.

Claims (4)

1. The utility model provides a broken processingequipment of rivers impact type bubble embedding type ore which characterized in that: the device comprises a main body supporting mechanism (1), a cross-flow type water circulation impact type ore pre-crushing mechanism (5), an impact flow cooling type bubble explosion type water source cooling storage mechanism (18), an electrostatic adsorption type metal retention type dust collecting and filtering mechanism (28), a pulse injection type anti-blocking type filter screen impurity removing mechanism (37), a stirring type broken stone sorting and blanking mechanism (42), a linkage type broken stone dust-free transmission mechanism (49), a broken stone butt-collision type extrusion crushing mechanism (56) and a magnetic power type pushing type broken stone cleaning mechanism (62), wherein the main body supporting mechanism (1) comprises a bottom plate (2), a supporting frame (3), a bearing plate (4), a dust-free crushing box body (7) and a transmission frame (50), the supporting frame (3) is symmetrically arranged on the upper wall of one end of the bottom plate (2), the bearing plate (4) is symmetrically arranged on the upper wall of one end of the bottom plate (2) far away from the supporting frame (3), the dust-free crushing box body (7) is arranged between one side of the bearing plate (4) far away from the bottom plate (2), the dust-free crushing box body (7) is a cavity with one open end, the transmission frame (50) is arranged on the upper wall of the support frame (3), one side of the transmission frame (50) far away from the support frame (3) penetrates through the opening of the dust-free crushing box body (7) and is arranged on the inner wall of one side of the dust-free crushing box body (7), the cross-flow type water circulation impact type ore pre-crushing mechanism (5) is arranged at one end of the dust-free crushing box body (7) close to the support frame (3), the impact flow cooling type bubble explosion type water source cooling storage mechanism (18) is arranged on the upper wall of the bottom plate (2), the electrostatic adsorption type metal retention type dust collection filter mechanism (28) is arranged on the side wall of the dust-free crushing box body (7), the pulse injection type anti-blockage type filter screen impurity removal mechanism (37) is arranged on the electrostatic adsorption type metal retention type dust collection filter mechanism (28) side wall, the stirring type crushed stone sorting and blanking mechanism (42) is arranged at one end, close to the support frame (3), of the transmission frame (50), the linkage type crushed stone dust-free transmission mechanism (49) is arranged on the inner wall of the transmission frame (50), the crushed stone colliding type extrusion crushing mechanism (56) is arranged on a dust-free crushing box body (7) below one end, far away from the support frame (3), of the transmission frame (50), and the magnetic power type pushing type crushed stone cleaning mechanism (62) is arranged at the bottom of the dust-free crushing box body (7); the stirring type crushed stone sequencing and blanking mechanism (42) comprises a blanking box body (43), a blanking motor (44), a stirring shaft (45), a stirring roller (46), a driving gear (47) and a fixed support (48), wherein the fixed support (48) is arranged on one end upper wall of a transmission frame (50) far away from a dust-free crushing box body (7), the blanking box body (43) is arranged on one side of the fixed support (48) far away from the transmission frame (50), the blanking box body (43) is arranged in a vertically through mode, the stirring shaft (45) is rotatably arranged on the inner wall of the blanking box body (43), the stirring roller (46) is arranged on the outer side of the stirring shaft (45), the blanking motor (44) is arranged on the side wall of the blanking box body (43), the stirring shaft (45) penetrates through the blanking box body (43) and is arranged at the power output end of the blanking motor (44), one end of the stirring shaft (45) far away from the blanking motor (44) penetrates through the blanking box body (43), the driving gear (47) is arranged at one end of the stirring shaft (45) far away from the blanking motor (44); the linkage type gravel dust-free conveying mechanism (49) comprises conveying roll shafts (51), conveying rollers (52), a conveying belt (53), driven gears (54) and gear belts (55), wherein multiple groups of conveying roll shafts (51) are rotatably arranged on the inner wall of a conveying frame (50), the conveying rollers (52) are arranged on the outer side of the conveying roll shafts (51), the conveying belts (53) are wound on the conveying rollers (52), the conveying roll shafts (51) at one end, close to a driving gear (47), of the conveying frame (50) penetrate through the inner wall of the conveying frame (50), the driven gears (54) are arranged at one end, penetrating through the conveying frame (50), of the conveying roll shafts (51), the gear belts (55) are wound between the driving gear (47) and the driven gears (54), and the gear belts (55) are respectively meshed with the driving gear (47) and the driven gears (54); the through-flow type water circulation impact type ore pre-crushing mechanism (5) comprises a high-pressure water pump (6), a water suction pipe (9), a water outlet pipeline (10), a flow dividing pipeline (11), a support plate (12), a connecting pipeline (13), an annular impact pipeline (14), an impact spray head (15), a water return port (16) and a filter screen (17), wherein the high-pressure water pump (6) is arranged on the upper wall of a bottom plate (2) on one side of a dust-free crushing box body (7), the water suction pipe (9) is arranged at the power input end of the high-pressure water pump (6), the water outlet pipeline (10) is arranged at the power output end of the high-pressure water pump (6), the support plate (12) is symmetrically arranged on one side, close to the high-pressure water pump (6), of the dust-free crushing box body (7), the flow dividing pipeline (11) is arranged between the support plates (12), one side, far away from the high-pressure water pump (6), of the water outlet pipeline (10) is communicated with the flow dividing pipeline (11), the annular impact pipelines (14) are arranged on the upper wall of the transmission frame (50) in multiple groups, the connecting pipeline (13) penetrates through the side wall of the dust-free crushing box body (7) and is communicated with the annular impact pipeline (14), the water source is divided by the dividing pipeline (11) and is conveyed into the connecting pipeline (13), the connecting pipeline (13) conveys the water source into the annular impact pipeline (14), the impact nozzles (15) are arranged on the annular impact pipeline (14) in multiple groups in a communicated manner, the impact nozzles (15) are arranged opposite to the transmission frame (50), the water return port (16) is arranged at the bottom of the dust-free crushing box body (7) below the impact nozzles (15), and the filter screen (17) is arranged on the inner wall of the water return port (16); the electrostatic adsorption type metal retention type dust collection and filtration mechanism (28) comprises a dust collection box body (29), an exhaust port (30), an air suction fan (31), a metal net electrostatic adsorption layer (32), a wide-mouth dust suction head (33), a dust collection pipeline (34), a conveying pipeline (35), a fixing clamp (36) and an electrostatic generator (68), wherein the dust collection box body (29) is arranged on one side of a dust-free crushing box body (7) far away from a shunt pipeline (11), the exhaust port (30) is arranged on the upper wall of the dust collection box body (29), the air suction fan (31) is arranged in the exhaust port (30), the metal net electrostatic adsorption layer (32) is arranged on the inner wall of the dust collection box body (29), the dust collection pipeline (34) is arranged above the dust-free crushing box body (7), the two ends of the dust collection pipeline (34) are penetrated inside the dust-free crushing box body (7), and the wide-mouth dust suction head (33) is symmetrically arranged at the two ends of the dust collection pipeline (34), the wide-mouth dust collection head (33) is arranged inside the dust-free crushing box body (7), the wide-mouth dust collection head (33) is communicated with a dust collection pipeline (34), the conveying pipeline (35) is communicated with the dust collection pipeline (34) and the dust collection box body (29), the fixing clamp (36) is arranged between the dust collection box body (29) and the conveying pipeline (35), the electrostatic generator (68) is arranged on one side, far away from the dust-free crushing box body (7), of the dust collection box body (29), and the power end of the electrostatic generator (68) penetrates through the dust collection box body (29); the impact flow cooling type bubble explosion water source cooling storage mechanism (18) comprises a water storage box body (19), an ultrasonic oscillator (20), a vortex tube (21), an air compressor (22), a compressed gas discharge pipeline (23), a compression air inlet pipeline (24), an air cooling pipeline (25), a cooling copper plate (26) and a pipeline clamp (27), wherein the water storage box body (19) is arranged on the upper wall of a bottom plate (2) below a water return port (16), the water storage box body (19) is a cavity with an upper end open, one side of a water suction pipe (9) far away from a high-pressure water pump (6) is communicated with the water storage box body (19), the ultrasonic oscillator (20) is arranged on the side wall of the water storage box body (19), the power end of the ultrasonic oscillator (20) penetrates through the inside of the water storage box body (19), the vortex tube (21) is arranged on one side of a dust collection box body (29) far away from a fixing clamp (36), and the air compressor (22) is arranged on the side wall of a crushing box body (7) on one side of the dust-free vortex tube (21), the compressed gas discharge pipeline (23) is arranged at the power output end of the air compressor (22), the compressed gas inlet pipeline (24) is communicated between the compressed gas discharge pipeline (23) and the power input end of the vortex tube (21), the cold air pipeline (25) is communicated between the water storage box body (19) and the power output end of the vortex tube (21), the pipeline clamp (27) is arranged between the side wall of the dust collection box body (29) and the cold air pipeline (25), and the cooling copper plate (26) is arranged at the bottom wall of one end, close to the cold air pipeline (25), of the water storage box body (19); pulse injection formula prevents stifled type filter screen edulcoration mechanism (37) includes electromagnetic pulse valve (38), injection pipeline (39), jet orifice (40), pulse admission line (41) and control valve (71), dust collection box (29) lateral wall above vortex tube (21) is located in electromagnetic pulse valve (38), dust collection box (29) inner wall above metal mesh electrostatic adsorption layer (32) is located in injection pipeline (39), and injection pipeline (39) run through dust collection box (29) inner wall and locate electromagnetic pulse valve (38) jet-propelled end, jet orifice (40) are located and are sprayed pipeline (39) diapire, compressed gas discharge pipe way (23) and electromagnetic pulse valve (38) inlet end are located in pulse admission line (41) intercommunication, control valve (71) are located on pulse admission line (41).

2. A water-impact gas bubble-insertion type ore crushing processing device according to claim 1, wherein: the crushing and crushing mechanism (56) comprises a crushing motor (57), a crushing shaft (58), a crushing roller (59), a linkage gear (60), an auxiliary gear (61), a feed opening (70) and a storage box (69), wherein the crushing motor (57) is arranged on the side wall of one end of a dust-free crushing box body (7) far away from a support frame (3), the crushing shaft (58) is symmetrically arranged on the inner wall of one end of the dust-free crushing box body (7) far away from a feed box body (43), the crushing shaft (58) is rotatably arranged on the inner wall of the dust-free crushing box body (7), the crushing roller (59) is arranged on the outer side of the crushing shaft (58), one end of the crushing shaft (58) far away from the crushing motor (57) penetrates through the inner wall of the dust-free crushing box body (7) and is arranged outside the dust-free crushing box body (7), the linkage gear (60) is arranged on one end of the crushing shaft (58) far away from the crushing motor (57), auxiliary gear (61) are located on broken axle (58) of linkage gear (60) one side, linkage gear (60) mesh mutually with auxiliary gear (61), dustless broken box (7) bottom of broken roller (59) below is located in feed opening (70), bottom plate (2) upper wall of feed opening (70) below is located in storage case (69), and storage case (69) are the cavity of upper end opening.

3. A water-impact gas bubble-insertion type ore crushing processing device according to claim 2, wherein: magnetism powered promotion type rubble clearance mechanism (62) include sliding tray (63), slider (64), clearance board (65), clearance electro-magnet (66) and fixed electro-magnet (67), dustless broken box (7) bottom both sides inner wall is located to sliding tray (63) symmetry, and sliding tray (63) are one end open-ended cavity setting, slider (64) slide and locate in sliding tray (63), clearance board (65) are located between slider (64), one side that feed opening (70) were kept away from in clearance board (65) is located in clearance electro-magnet (66), the one end diapire that feed opening (70) were kept away from in dustless broken box (7) is located in fixed electro-magnet (67), and clearance electro-magnet (66) and fixed electro-magnet (67) set up relatively.

4. A water-impact gas bubble-insertion type ore crushing processing device according to claim 3, wherein: the side wall of the dust-free crushing box body (7) is provided with a controller (8), and the controller (8) is respectively electrically connected with the high-pressure water pump (6), the ultrasonic oscillator (20), the air compressor (22), the suction fan (31), the electrostatic generator (68), the electromagnetic pulse valve (38), the blanking motor (44), the crushing motor (57), the cleaning electromagnet (66) and the fixed electromagnet (67).

Images