CN113601330A - Anion adsorption type energy utilization pump body multi-dimensional processing device - Google Patents

Abstract

The invention discloses a negative ion adsorption type energy utilization pump body multidimensional processing device which comprises a main body supporting mechanism, a magnetomotive open type waste scrap collecting and lifting mechanism, a centrifugal waste gas impurity electrostatic state medium adsorption mechanism, a circulating water resource utilization type cooling mechanism, a multi-angle arc-state pump body surface walking and polishing mechanism, a pneumatic translation adjusting and clamping mechanism and a new energy type waste gas power recycling mechanism. The invention belongs to the technical field of submersible pump processing, and particularly relates to a multi-dimensional processing device for an anion adsorption type energy utilization pump body; the invention aims at the problem of no dead angle on the surface of the pump body, creatively utilizes the one-dimensional variable multi-dimensional principle, and polishes through moving from a single-point fixed polishing to a plurality of points, thereby realizing the omnibearing, multi-angle and no dead angle polishing on the surface of the pump body and solving the technical problem that the surface of the pump body can not be polished at different angles in the prior art.

Description

Anion adsorption type energy utilization pump body multi-dimensional processing device

Technical Field

The invention belongs to the technical field of submersible pump processing, and particularly relates to a multi-dimensional processing device for an anion adsorption type energy utilization pump body.

Background

The submersible pump is an important device for pumping water from a deep well, when in use, the whole unit is submerged into water to work, and the underground water is pumped to the ground surface, so that the submersible pump is used for domestic water, mine emergency rescue, industrial cooling, farmland irrigation, seawater lifting and ship load regulation, and can also be used for fountain landscape.

The patent No. CN110026858A discloses a surface treatment device for producing a submersible pump, which comprises a frame, a grinding box, an electric telescopic rod, a support, a screw rod, a locking universal wheel, a rotating ball, a support rod, a turntable, a grinding head, a motor sleeve, a thread fixing rod, a fixing frame and a thread hole, wherein the frame is of a hollow structure, four groups of locking universal wheels are arranged at the bottom end of the frame, the grinding box is arranged at the bottom end inside the frame, the upper end of the grinding box is provided with an opening, the electric telescopic rod is arranged at the top end of the frame, the output end of the electric telescopic rod is fixedly connected with the support, the fixing frame is arranged at the middle position of the support and is of a spherical structure, the surface of the fixing frame is provided with a thread hole, the device can grind the surface of the pump body at multiple angles, is convenient for cooling the grinding cutter in cold water, but can not be recycled after filtering the grinding water, the use efficiency of the grinding device is reduced.

The fixed unable removal of current grinding device head of polishing position, need rotate the part by oneself when polishing different angles and polish, waste time and energy, and polish unstably, the deviation appears easily, grinding efficiency is not high, can not filter the back circulation use to the moisture that polishes and use, can not discharge after filtering treatment to the dust that produces in polishing, and can not carry out resource utilization to the impact force that wind or water caused, thereby make surface treatment device for the submerged pump availability factor low, be difficult to satisfy people's demand.

Disclosure of Invention

Aiming at the situation and overcoming the defects of the prior art, the invention provides the anion adsorption type energy utilization pump body multidimensional processing device, aiming at the problem of no dead angle on the surface of the pump body, creatively applies the one-dimensional variable multidimensional principle (changing the one-dimensional linear motion object into two-dimensional plane motion or three-dimensional space motion) to the technical field of submersible pump processing, realizes all-dimensional, multi-angle and no dead angle on the surface of the pump body by polishing from single-point fixing to multi-point moving motion, and solves the technical problem that the surface of the pump body can not be polished at different angles in the prior art; under the condition of no intervention of expensive dust removal equipment and sensor elements, a mechanical system substitution principle (an electric field, a magnetic field and an electromagnetic field which interact with an object) is creatively applied to the technical field of submersible pump processing, the separation of impurities in the waste gas is realized by adopting magnetic power to drive centrifugal rotation motion, and fine dust in the waste gas is adsorbed by negative ions generated by an electrostatic generator, so that the technical problem that the waste gas cannot be discharged in a dust-free manner is solved, and the technical problems that the waste gas is required to be discharged quickly (the discharge efficiency of the waste gas is improved) and the waste gas is not required to be discharged quickly (the dust filtering efficiency in the waste gas is reduced easily due to the fact that the waste gas is discharged too quickly) are solved; the new energy type waste gas power recycling mechanism is arranged, so that a new energy concept is really combined into practice to be applied, pollution-free resources are fully utilized, and the overall energy consumption of equipment is reduced; the magnetic power type open type scrap collecting and lifting mechanism is arranged by means of an intermediary principle (the intermediary is used for realizing required actions), so that complicated operation caused by a mechanical lifting structure is avoided to a certain extent, and the lifting adjustment of the pump processing platform is completed through the homopolar repulsion and heteropolar attraction characteristics of the electromagnet.

The technical scheme adopted by the invention is as follows: the invention relates to a multi-dimensional processing device of a negative ion adsorption type energy utilization pump body, which comprises a main body supporting mechanism, a magnetomotive open type waste scrap collecting and lifting mechanism, a centrifugal waste gas impurity electrostatic state medium adsorption mechanism, a circulating water resource utilization type cooling mechanism, a multi-angle arc state pump body surface walking and polishing mechanism, a pneumatic translation adjusting and clamping mechanism and a new energy type waste gas power recycling mechanism, wherein the main body supporting mechanism comprises a base and an arch structure, the arch structure is arranged on the upper wall of one end of the base, the magnetomotive open type waste scrap collecting and lifting mechanism is arranged on the upper wall of one end of the base close to the arch structure, the magnetomotive open type waste scrap collecting and lifting mechanism lifts a processing platform through the magnetomotive force to conveniently collect waste scraps generated by processing, the centrifugal waste gas impurity electrostatic state medium adsorption mechanism is arranged on the upper wall of one end of the base far away from the magnetomotive open type waste scrap collecting and lifting mechanism, the centrifugal waste gas impurity electrostatic state medium adsorption mechanism adopts a centrifugal motion structure to separate impurities in waste gas, fine impurities are adsorbed by electrostatic ions, the circulating water resource utilization type cooling mechanism is arranged on the upper wall of a base between the magnetic power type open type waste chip collecting and lifting mechanism and the centrifugal waste gas impurity electrostatic state medium adsorption mechanism, the circulating water resource utilization type cooling mechanism adopts a circulating structure principle to cool a water source, the multi-angle arc-shaped pump body surface walking and polishing mechanism is arranged on an arch structure, the multi-angle arc-shaped pump body surface walking and polishing mechanism carries out multi-angle movement through gear and rack meshing, the pneumatic type translation adjusting and clamping mechanism is arranged on the magnetic power type open type waste chip collecting and lifting mechanism, and the pneumatic type translation adjusting and clamping mechanism rapidly clamps and fixes a pump body through a pneumatic cylinder, new forms of energy waste gas power recycle mechanism locates the upper wall of keeping away from circulating water resource utilization type cooling mechanism one side, and new forms of energy waste gas power recycle mechanism adopts the new forms of energy theory to realize the make full use of to the waste gas impact force.

As a further preferred aspect of the present invention, the magnetomotive open type scrap collecting and lifting mechanism includes a magnetomotive fixed electromagnet, a magnetomotive lifting electromagnet, a lifting sliding groove, a sliding connecting rod, a lifting platform, a support, a scrap collecting box body, a scrap filtering net and a clamping frame, the arched door structure is in an inverted U-shaped configuration, the lifting sliding groove is symmetrically disposed on inner walls of two sides of the arched door structure, the lifting sliding groove is a cavity with an opening at one end, the sliding connecting rod is slidably disposed in the lifting sliding groove, the lifting platform is disposed between the sliding connecting rods, the support is symmetrically disposed on an upper wall of the lifting platform, the scrap collecting box body is disposed between sides of the support far away from the lifting platform, the scrap collecting box body is a cavity with an opening at an upper end, the scrap filtering net is disposed on an inner wall of the scrap collecting box body, the clamping frame is disposed on an upper wall of the scrap collecting box body, the magnetomotive lifting electromagnet is disposed on a bottom wall of the lifting platform, the magnetic power fixed electromagnet is arranged on the upper wall of the base below the lifting platform, pushes the magnetic power lifting electromagnet to ascend through repulsion force, drives the lifting platform to ascend in a sliding mode along a lifting sliding groove through a sliding connecting rod, and drives the clamping frame to adjust the height through the scrap recovery box body.

Preferably, the centrifugal waste gas impurity electrostatic state medium adsorption mechanism comprises a waste gas impurity filtering tower, an unpowered rotary cylinder body, an impurity throwing outlet, a fixing frame, a waste gas recovery filtering pump, an air exhaust pipeline, a filtering pipeline, an air inlet pipeline, a three-phase coil, a power magnet, a waste gas suction hose, an electrostatic generator and a wire mesh filling layer, wherein the fixing frame is symmetrically arranged at two sides of the arch structure, the waste gas impurity filtering tower is arranged between one sides of the fixing frame far away from the arch structure, the waste gas recovery filtering pump is arranged on the upper wall of the waste gas impurity filtering tower, the air exhaust pipeline is arranged at the power input end of the waste gas recovery filtering pump, the waste gas suction hose is communicated between a waste scrap recovery box body and the air exhaust pipeline, the air inlet pipeline is communicated with the bottom wall of the waste gas impurity filtering tower, and the rotary cylinder body is rotatably arranged between the air inlet pipeline and the air exhaust pipeline, the exhaust pipeline and the air inlet pipeline are respectively communicated with the unpowered rotary barrel, the wire mesh filling layer is arranged at the bottom of the unpowered rotary barrel, a plurality of groups of impurity throwing outlets are arranged on the side wall of the unpowered rotary barrel, the filtering pipeline is communicated between the upper wall of the waste gas impurity filtering tower and the power output end of the waste gas recovery filtering pump, the air inlet pipeline is arranged at the outer side of the unpowered rotary barrel, the power magnets are symmetrically arranged on the inner walls at the two sides of the waste gas impurity filtering tower, the power magnets and the three-phase coil are horizontally arranged, the electrostatic generator is arranged on the side wall of the waste gas impurity filtering tower, the power end of the electrostatic generator penetrates through the waste gas impurity filtering tower and is arranged in the waste gas impurity filtering tower, the waste gas recovery filtering pump extracts dust generated by polishing the pump body through a waste gas suction hose, and air containing the dust enters the unpowered rotary barrel through the filtering pipeline, the static generator starts to generate static ions through the power end, the static ions enable the interior of the waste gas impurity filtering tower to be in a static state, the static ions pass through the impurity throwing outlet and are adsorbed on the wire mesh filling layer, the three-phase coil is electrified, the unpowered rotary cylinder body rotates under the acting force of the three-phase coil and the power magnet magnetic field, air containing dust carries out centrifugal motion in the unpowered rotary cylinder body, dust with larger weight is attached to the inner wall of the unpowered rotary cylinder body under the action of gravity, the dust enters the waste gas impurity filtering tower through the impurity throwing outlet, dust with smaller weight is filtered by the wire mesh filling layer and then is discharged out of the unpowered rotary cylinder body through the air inlet pipeline, and the wire mesh filling layer adsorbs the dust under the acting force of the static ions.

Further, the circulating water resource utilization type cooling mechanism comprises a cooling water cooler, a cold water conveying telescopic hose, a water outlet pipeline, a water pumping pipeline, a cooling pipeline, a pipeline clamp, a cooling water backflow pipeline, a water storage box body, a recovery telescopic hose, a recovery water pump and a water inlet pipeline, wherein the water storage box body is arranged on the upper wall of the base on one side of the arch door structure, the cooling water cooler is arranged on the upper wall of the water storage box body, the water pumping pipeline is communicated between the power input end of the cooling water cooler and the upper wall of the water storage box body, the water outlet pipeline is arranged at the power output end of the cooling water cooler, the pipeline clamp is arranged on the upper wall of the clamping frame, the cooling pipeline is arranged on the pipeline clamp, the cold water conveying telescopic hose is communicated between the cooling pipeline and the water outlet pipeline, the recovery water pump is arranged on the upper wall of the water storage box body on one side of the cooling water cooler, the water inlet pipeline is communicated between the upper wall of the water storage box body and the power output end of the recovery water pump, the cooling water return line locates recovery water pump power input end, it locates between sweeps recovery box diapire and the cooling water return line to retrieve the bellows intercommunication, the moisture that cooling water-cooled generator extracted the water storage tank in through the pipeline that draws water cools down, moisture gets into in the flexible hose of cold water transport through outlet conduit, moisture in the flexible hose of cold water transport cools off the instrument of polishing and the pump body through the cooling tube blowout, the cooling water after the use falls into sweeps recovery bottom of the box after the sweeps filter screen filters, in the moisture after the recovery water pump will filter carried the cooling water return line through retrieving flexible hose, the moisture in the cooling water return line flows into the water storage tank and cools down once more.

Specifically, the multi-angle arc-state pump body surface walking and polishing mechanism comprises a walking force-borrowing rack, an arc-shaped through groove, an arc-shaped sliding groove, a multi-angle walking sliding rod, a connecting block, a double-shaft motor, a walking gear, an electric telescopic rod, a polishing motor and a polishing head, wherein the arc-shaped through groove is formed in the upper wall of the arched door structure, the arc-shaped through groove is communicated with the arc-shaped through groove, the arc-shaped through grooves are symmetrically formed in the inner walls of the two sides of the arc-shaped through groove, the arc-shaped through groove is oppositely arranged, the multi-angle walking sliding rod is slidably arranged in the arc-shaped sliding groove, the connecting block is arranged between the multi-angle walking sliding rods, the double-shaft motor is arranged on the upper wall of the connecting block, the walking gear is symmetrically arranged on the power output ends of the two sides of the double-shaft motor, the walking force-borrowing rack is symmetrically arranged on the upper wall of the arched door structure on the two sides of the arc-shaped through groove, and the walking gear is meshed with the walking force-borrowing rack, electric telescopic handle locates the connecting block diapire, grinding motor locates electric telescopic handle and keeps away from one side of connecting block, grinding head locates grinding motor power end, the biax motor drives the walking gear revolve, the rack toothing is borrowed with the walking to the walking gear, the walking gear is borrowed the rack through the walking and is driven the connecting block walking, the connecting block passes through multi-angle walking slide bar and slides along the circular arc spout, the connecting block drives to drive grinding motor through electric telescopic handle and carries out multi-angle migration, electric telescopic handle extension or shorten and drive grinding motor and go up and down and carry out the height position adjustment, grinding motor drives grinding head and polishes to the pump body surface.

The pneumatic type translation adjusting clamping mechanism comprises a clamping cylinder, a clamping block and a bearing plate, wherein the clamping cylinder is symmetrically arranged on two sides of a clamping frame, the power end of the clamping cylinder penetrates through the side wall of the clamping frame and is arranged between the inner walls of the clamping frame, the clamping block is arranged at the power end of the clamping cylinder, the clamping cylinder is arranged relatively, the bearing plate is arranged on the inner walls of the clamping frame, a pump body to be polished is placed on the bearing plate, and the clamping cylinder extends to drive the clamping block to clamp and fix the pump body.

Further, the new energy type waste gas power recycling mechanism comprises an impact force utilization box body, fan blades, a rotating shaft, a rotating magnet, a magnet carrier, a stator coil and an exhaust pipeline, wherein the impact force utilization box body is arranged on the upper wall of the base at one side of the waste gas impurity filtering tower, which is far away from the water storage tank body, one end of the air inlet pipeline, which is far away from the unpowered rotating cylinder body, is communicated with the impact force utilization box body, the rotating shaft is rotatably arranged on the inner wall of the impact force utilization box body at one side, which is far away from the air inlet pipeline, of the air inlet pipeline, the magnet carrier is arranged on the outer side of the rotating shaft, a plurality of groups of rotating magnets are arranged on the outer side of the magnet carrier, the rotating magnets which are adjacently arranged are heteropolars, the stator coil is arranged on the inner wall of the impact force utilization box body at the outer side of the rotating magnet, the exhaust pipeline is symmetrically arranged on the side wall of one end, which is far away from the air inlet pipeline, of the filtered waste gas enters the impact force utilization box body through the air inlet pipeline, waste gas impacts the fan blades, the fan blades drive the rotating shaft to rotate, the rotating shaft drives the magnet carrier to rotate, the magnet carrier drives the rotating magnet to rotate inside the stator coil, and when one part of conductors of the closed circuit do cutting magnetic induction line movement, induced current can be generated on the conductors, so that power generation is performed.

Still further, the lateral wall of the scrap recovery box body is provided with a controller, and the controller is respectively and electrically connected with the magnetomotive fixed electromagnet, the magnetomotive lifting electromagnet, the three-phase coil, the electrostatic generator, the cooling water-cooling machine, the recovery water pump, the double-shaft motor, the polishing motor and the clamping cylinder.

Furthermore, the upper wall of the base is provided with an energy storage unit which is electrically connected with the controller and the stator coil respectively.

The invention with the structure has the following beneficial effects: according to the scheme, the height of a pump body treatment platform is adjusted by a magnetomotive open type waste chip collecting and lifting mechanism which is arranged according to the principle that like poles repel each other and unlike poles attract each other, the method is used for lifting and adjusting the treatment platform through the magnetomotive force, the use of expensive equipment is reduced, the complex operation of a lifting structure is avoided, a magnetomotive force fixing electromagnet pushes a magnetomotive force lifting electromagnet to ascend through repulsion force, the magnetomotive force lifting electromagnet drives a lifting platform to slide and ascend along a lifting sliding groove through a sliding connecting rod, and the lifting platform drives a clamping frame to adjust the height through a waste chip recovery box body; the centrifugal waste gas impurity electrostatic state medium adsorption mechanism arranged according to the universal gravitation idea realizes the separation of impurities in waste gas, the method rotates the waste gas at a high speed through a centrifugal motion structure, so that impurities with overlarge weight are thrown out of the waste gas, the electrostatic adsorption principle is adopted to adsorb fine dust in the waste gas through electrostatic ions, the dust-free emission of air is achieved, the environment is protected, the reliability is high, the air containing dust enters the unpowered rotary cylinder body through a filtering pipeline through an air exhaust pipeline, the electrostatic generator is started to generate electrostatic ions through a power end, the electrostatic ions enable the interior of the waste gas impurity filtering tower to be in an electrostatic state, the electrostatic ions pass through an impurity throwing outlet and are adsorbed on a wire mesh filling layer, the three-phase coil is electrified, the unpowered rotary cylinder body rotates under the acting force of the three-phase coil and a power magnet magnetic field, and the air containing dust performs centrifugal motion in the unpowered rotary cylinder body, the dust with larger weight is attached to the inner wall of the unpowered rotary cylinder under the action of gravity, enters the waste gas impurity filtering tower through the impurity throwing-out opening, is filtered by the wire gauze filling layer and then is discharged out of the unpowered rotary cylinder through the air inlet pipeline, and the wire gauze filling layer adsorbs the dust under the action of electrostatic ions; the circulating water resource utilization type cooling mechanism arranged by adopting a circulating structure principle realizes the circulating cooling use of cooling water, the method effectively utilizes water resources, the used cooling water is filtered by a scrap filter screen and then falls into the bottom of a scrap recovery box body, a recovery water pump recovers the filtered water, and the recovery water pump sucks the filtered water into a water storage box body through a cooling water return pipeline through a recovery telescopic hose to cool the water again, so that the water is recycled; the multi-angle and all-dimensional polishing treatment on the pump body is realized through the multi-angle arc-shaped pump body surface walking polishing mechanism.

Drawings

FIG. 1 is a schematic view of the overall structure of a multi-dimensional pump processing apparatus of the present invention;

FIG. 2 is a perspective view of an anion-adsorbing energy-utilizing pump-body multi-dimensional processing device according to the present invention;

FIG. 3 is a front view of an anion-adsorbing energy-utilizing pump-body multi-dimensional processing device according to the present invention;

FIG. 4 is a rear view of a multi-dimensional pump processing apparatus of the present invention;

FIG. 5 is a left side view of an anion-adsorbing energy-utilizing pump-body multi-dimensional processing apparatus according to the present invention;

FIG. 6 is a right side view of an anion-adsorbing energy-utilizing pump-body multi-dimensional processing apparatus according to the present invention;

FIG. 7 is a top view of an anion-adsorbing energy-utilizing pump-body multi-dimensional processing apparatus according to the present invention;

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

FIG. 9 is a sectional view of portion B-B of FIG. 3;

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

fig. 11 is a circuit diagram of a new energy type exhaust power recycling mechanism of a negative ion adsorption type energy utilization type pump body multi-dimensional processing device;

fig. 12 is a block diagram of a new energy type exhaust power recycling mechanism of a negative ion adsorption type energy utilization type pump body multi-dimensional processing device.

Wherein, 1, a main body supporting mechanism, 2, a base, 3, an energy storage unit, 4, an arch door structure, 5, a magnetomotive open type scrap collecting and lifting mechanism, 6, a magnetomotive fixed electromagnet, 7, a magnetomotive lifting electromagnet, 8, a lifting sliding groove, 9, a sliding connecting rod, 10, a lifting platform, 11, a bracket, 12, a scrap recycling box body, 13, a controller, 14, a scrap filtering screen, 15, a clamping frame, 16, a centrifugal type waste gas impurity electrostatic state medium adsorption mechanism, 17, a waste gas impurity filtering tower, 18, an unpowered rotating cylinder, 19, an impurity throwing outlet, 20, a fixing frame, 21, a waste gas recycling filtering pump, 22, an air extraction pipeline, 23, a filtering pipeline, 24, an air inlet pipeline, 25, a three-phase coil, 26, a power magnet, 27, a waste gas suction hose, 28, a water resource electrostatic generator, 29, a wire gauze filling layer, 30, a circulating type cooling mechanism, 31. a cooling water cooler, 32, a cold water conveying telescopic hose, 33, a water outlet pipeline, 34, a water pumping pipeline, 35, a cooling pipeline, 36, a pipeline clamp, 37, a cooling water return pipeline, 38, a water storage tank body, 39, a recovery telescopic hose, 40, a recovery water pump, 41, a water inlet pipeline, 42, a stator coil, 43, an exhaust pipeline, 44, a multi-angle arc-state pump body surface walking and polishing mechanism, 45, a walking force-borrowing rack, 46, an arc-shaped through groove, 47, an arc-shaped sliding groove, 48, a multi-angle walking sliding rod, 49, a connecting block, 50, a double-shaft motor, 51, a walking gear, 52, an electric telescopic rod, 53, a polishing motor, 54, a polishing head, 55, a pneumatic translation adjusting and clamping mechanism, 56, a clamping cylinder, 57, a clamping block, 58, a bearing plate, 59, a new energy type waste gas power recycling mechanism, 60, an impact force utilizing box body, 61 and fan blades, 62. a rotating shaft 63, a rotating magnet 64 and a magnet carrier.

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

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, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope 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, and are only for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the device or element referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus should not be construed as limiting the present invention.

As shown in fig. 1-2, the invention provides an anion adsorption type energy utilization pump body multidimensional processing device, which comprises a main body supporting mechanism 1, a magnetomotive open type waste scrap collecting and lifting mechanism 5, a centrifugal waste gas impurity electrostatic state medium adsorption mechanism 16, a circulating water resource utilization type cooling mechanism 30, a multi-angle arc state pump body surface walking and polishing mechanism 44, a pneumatic translation adjusting and clamping mechanism 55 and a new energy type waste gas power recycling and utilizing mechanism 59, wherein the main body supporting mechanism 1 comprises a base 2 and an arch structure 4, the arch structure 4 is arranged on the upper wall of one end of the base 2, the magnetomotive open type waste scrap collecting and lifting mechanism 5 is arranged on the upper wall of one end of the base 2 close to the arch structure 4, the magnetomotive open type waste scrap collecting and lifting mechanism 5 lifts a processing platform through magnetomotive force, so as to collect waste scraps generated by processing, the centrifugal waste gas impurity electrostatic state medium adsorption mechanism 16 is arranged on the upper wall of one end of the base 2 far away from the magnetic power type open type waste gas impurity electrostatic state medium adsorption mechanism 5, the centrifugal waste gas impurity electrostatic state medium adsorption mechanism 16 adopts a centrifugal motion structure to separate impurities in waste gas, fine impurities are adsorbed by electrostatic ions, the circulating water resource utilization type cooling mechanism 30 is arranged on the upper wall of the base 2 between the magnetic power type open type waste gas impurity electrostatic state medium adsorption mechanism 16 and the magnetic power type open type waste gas impurity electrostatic state medium adsorption mechanism 5, the circulating water resource utilization type cooling mechanism 30 adopts a jet flow principle to realize low energy consumption, no pollution and no equipment cooling on a water source, the multi-angle arc-state pump body surface walking polishing mechanism 44 is arranged on the arched door structure 4, and the multi-angle arc-state pump body surface walking polishing mechanism 44 carries out multi-angle movement through the meshing of a gear and a rack, pneumatic type translation is adjusted fixture 55 and is located on the magnetic dynamic formula open type sweeps collects elevating system 5, and pneumatic type translation is adjusted fixture 55 and is carried out the centre gripping through the pneumatic cylinder fast to the pump body and fix, and new forms of energy waste gas power is retrieved and is utilized mechanism 59 and locate the upper wall of keeping away from circulating water resource utilization type cooling mechanism 30 one side, and new forms of energy waste gas power is retrieved and is utilized mechanism 59 and adopts the new forms of energy theory to realize the recycle to the waste gas impact force.

As shown in fig. 5, 6 and 9, the magnetomotive open type scrap collecting and lifting mechanism 5 comprises a magnetomotive fixed electromagnet 6, a magnetomotive lifting electromagnet 7, a lifting sliding groove 8, a sliding connecting rod 9, a lifting platform 10, a bracket 11, a scrap recovery box body 12, a scrap filtering net 14 and a clamping frame 15, wherein the arched door structure 4 is arranged in an inverted U shape, the lifting sliding groove 8 is symmetrically arranged on the inner wall of two sides of the arched door structure 4, the lifting sliding groove 8 is a cavity with an opening at one end, the sliding connecting rod 9 is slidably arranged in the lifting sliding groove 8, the lifting platform 10 is arranged between the sliding connecting rods 9, the bracket 11 is symmetrically arranged on the upper wall of the lifting platform 10, the scrap recovery box body 12 is arranged between one side of the bracket 11 far away from the lifting platform 10, the scrap recovery box body 12 is a cavity with an opening at the upper end, the scrap filtering net 14 is arranged on the inner wall of the scrap recovery box body 12, the clamping frame 15 is arranged on the upper wall of the scrap recovery box body 12, the magnetic power lifting electromagnet 7 is arranged on the bottom wall of the lifting platform 10, the magnetic power fixing electromagnet 6 is arranged on the upper wall of the base 2 below the lifting platform 10, the magnetic power fixing electromagnet 6 pushes the magnetic power lifting electromagnet 7 to ascend through repulsive force, the magnetic power lifting electromagnet 7 drives the lifting platform 10 to slide and ascend through a sliding connecting rod 9 along a lifting sliding groove 8, and the lifting platform 10 drives the clamping frame 15 to adjust the height through the scrap recovery box body 12.

As shown in fig. 2, fig. 7 and fig. 8, the centrifugal exhaust gas impurity electrostatic state medium adsorption mechanism 16 includes an exhaust gas impurity filtering tower 17, an unpowered rotary cylinder 18, an impurity throwing port 19, a fixing frame 20, an exhaust gas recovery filtering pump 21, an air suction pipeline 22, a filtering pipeline 23, an air inlet pipeline 24, a three-phase coil 25, a power magnet 26, an exhaust gas suction hose 27, an electrostatic generator 28 and a wire mesh filling layer 29, wherein the fixing frame 20 is symmetrically arranged at two sides of the arch structure 4, the exhaust gas impurity filtering tower 17 is arranged between the fixing frame 20 and the side far away from the arch structure 4, the exhaust gas recovery filtering pump 21 is arranged on the upper wall of the exhaust gas impurity filtering tower 17, the air suction pipeline 22 is arranged at the power input end of the exhaust gas recovery filtering pump 21, the exhaust gas suction hose 27 is arranged between the waste scrap recovery box 12 and the air suction pipeline 22, the air inlet pipeline 24 is arranged at the bottom wall of the exhaust gas impurity filtering tower 17, the unpowered rotary cylinder 18 is rotatably arranged between the air inlet pipeline 24 and the air suction pipeline 22, the air exhaust pipeline 22 and the air inlet pipeline 24 are respectively communicated with the unpowered rotary cylinder 18, the wire gauze filling layer 29 is arranged at the bottom of the unpowered rotary cylinder 18, a plurality of groups of impurity throwing ports 19 are arranged on the side wall of the unpowered rotary cylinder 18, the filter pipeline 23 is communicated between the upper wall of the waste gas impurity filter tower 17 and the power output end of the waste gas recovery filter pump 21, the air inlet pipeline 24 is arranged at the outer side of the unpowered rotary cylinder 18, the power magnets 26 are symmetrically arranged on the inner walls at two sides of the waste gas impurity filter tower 17, the power magnets 26 and the three-phase coil 25 are horizontally arranged, the electrostatic generator 28 is arranged on the side wall of the waste gas impurity filter tower 17, the power end of the electrostatic generator 28 penetrates through the waste gas impurity filter tower 17 and is arranged inside the waste gas impurity filter tower 17, the waste gas recovery filter pump 21 sucks dust generated by grinding the pump body through the waste gas suction hose 27, and air containing the dust enters the unpowered rotary cylinder 18 through the filter pipeline 23 through the air exhaust pipeline 22, the static generator 28 is started to generate static ions through the power end, the static ions enable the interior of the waste gas impurity filtering tower 17 to be in a static state, the static ions penetrate through the impurity throwing port 19 and are adsorbed on the wire mesh filling layer 29, the three-phase coil 25 is electrified, the unpowered rotary cylinder 18 rotates under the action of the magnetic fields of the three-phase coil 25 and the power magnet 26, air containing dust carries out centrifugal motion in the unpowered rotary cylinder 18, dust with larger weight is attached to the inner wall of the unpowered rotary cylinder 18 under the action of gravity and enters the interior of the waste gas impurity filtering tower 17 through the impurity throwing port 19, dust with smaller weight is filtered through the wire mesh filling layer 29 and then is discharged out of the unpowered rotary cylinder 18 through the air inlet pipeline 24, and the wire mesh filling layer 29 adsorbs the dust under the action of the static ions.

As shown in fig. 3, 4 and 10, the circulating water resource utilization type cooling mechanism 30 includes a cooling water cooler 31, a cold water conveying flexible hose 32, a water outlet pipe 33, a water pumping pipe 34, a cooling pipe 35, a pipe clamp 36, a cooling water return pipe 37, a water storage tank 38, a recovery flexible hose 39, a recovery water pump 40 and a water inlet pipe 41, the water storage tank 38 is disposed on the upper wall of the base 2 on one side of the arch door structure 4, the cooling water cooler 31 is disposed on the upper wall of the water storage tank 38, the water pumping pipe 34 is communicated between the power input end of the cooling water cooler 31 and the upper wall of the water storage tank 38, the water outlet pipe 33 is disposed on the power output end of the cooling water cooler 31, the pipe clamp 36 is disposed on the upper wall of the clamping frame 15, the cooling pipe 35 is disposed on the pipe clamp 36, the cold water conveying flexible hose 32 is communicated between the cooling pipe 35 and the water outlet pipe 33, the recovery water pump 40 is disposed on the upper wall of the water storage tank 38 on one side of the cooling water cooler 31, the water inlet pipe 41 is communicated with and arranged between the upper wall of the water storage tank body 38 and the power output end of the recovery water pump 40, the cooling water backflow pipe 37 is arranged at the power input end of the recovery water pump 40, the recovery telescopic hose 39 is communicated with and arranged between the bottom wall of the waste scrap recovery tank body 12 and the cooling water backflow pipe 37, the cooling water cooler 31 pumps water in the water storage tank body 38 through the water pumping pipe 34 to cool, the water enters the cold water conveying telescopic hose 32 through the water outlet pipe 33, the water in the cold water conveying telescopic hose 32 is sprayed out through the cooling pipe 35 to cool the grinding tool and the pump body, the cooled water falls into the bottom of the waste scrap recovery tank body 12 after being filtered through the waste scrap filter screen 14, the filtered water is conveyed into the cooling water backflow pipe 37 through the recovery telescopic hose 39 by the recovery water pump 40, and the water in the cooling water backflow pipe 37 flows into the water storage tank body 38 to cool again.

As shown in fig. 2, fig. 5, fig. 6 and fig. 9, the multi-angle circular arc state pump body surface walking polishing mechanism 44 comprises a walking force-borrowing rack 45, an arc-shaped through groove 46, a circular arc chute 47, a multi-angle walking slide bar 48, a connecting block 49, a dual-shaft motor 50, a walking gear 51, an electric telescopic rod 52, a polishing motor 53 and a polishing head 54, wherein the arc-shaped through groove 46 is arranged on the upper wall of the arched door structure 4, the arc-shaped through groove 46 is arranged in a through manner, the circular arc chutes 47 are symmetrically arranged on the inner walls at two sides of the arc-shaped through groove 46, the arc-shaped through groove 46 is arranged oppositely, the arc-shaped through groove 46 is a cavity with an opening at one end, the multi-angle walking slide bar 48 is arranged in the circular arc chute 47 in a sliding manner, the connecting block 49 is arranged between the multi-angle walking slide bars 48, the dual-shaft motor 50 is arranged on the upper wall of the connecting block 49, the walking gear 51 is symmetrically arranged on the power output ends at two sides of the dual-shaft motor 50, the walking force-borrowing rack 45 is symmetrically arranged on the upper wall of the arched door structure 4 at two sides of the arc-shaped through groove 46, walking gear 51 borrows power rack 45 to mesh with the walking, connecting block 49 diapire is located to electric telescopic handle 52, grinding motor 53 locates one side that electric telescopic handle 52 kept away from connecting block 49, grinding head 54 locates grinding motor 53 power end, double-shaft motor 50 drives walking gear 51 and rotates, walking gear 51 borrows power rack 45 with the walking and meshes, walking gear 51 borrows power rack 45 through the walking and drives connecting block 49 walking, connecting block 49 slides along circular arc spout 47 through multi-angle walking slide bar 48, connecting block 49 drives and drives grinding motor 53 through electric telescopic handle 52 and carry out multi-angle motion, electric telescopic handle 52 extension or shorten and drive grinding motor 53 lift high position, grinding motor 53 drives grinding head 54 and polishes the pump body surface.

As shown in fig. 1-3, the pneumatic type translational adjustment clamping mechanism 55 includes a clamping cylinder 56, a clamping block 57 and a bearing plate 58, the clamping cylinder 56 is symmetrically disposed on two sides of the clamping frame 15, a power end of the clamping cylinder 56 penetrates through a sidewall of the clamping frame 15 and is disposed between inner walls of the clamping frame 15, the clamping block 57 is disposed on a power end of the clamping cylinder 56, the clamping cylinder 56 is disposed oppositely, the bearing plate 58 is disposed on an inner wall of the clamping frame 15, a pump body to be polished is placed on the bearing plate 58, and the clamping cylinder 56 extends to drive the clamping block 57 to clamp and fix the pump body.

As shown in fig. 7-8, the new energy type exhaust gas power recycling mechanism 59 includes an impact force utilizing box 60, fan blades 61, a rotating shaft 62, a rotating magnet 63, a magnet carrier 64, a stator coil 42 and an exhaust duct 43, wherein the impact force utilizing box 60 is disposed on the upper wall of the base 2 on the side of the exhaust gas impurity filtering tower 17 far away from the water storage box 38, one end of the air inlet duct 24 far away from the unpowered rotary cylinder 18 is communicated with the impact force utilizing box 60, the rotating shaft 62 is rotatably disposed on the inner wall of the impact force utilizing box 60 far away from the air inlet duct 24, the magnet carrier 64 is disposed on the outer side of the rotating shaft 62, a plurality of sets of the rotating magnets 63 are disposed on the outer side of the magnet carrier 64, the adjacent rotating magnets 63 are heteropolar, the stator coil 42 is disposed on the inner wall of the impact force utilizing box 60 on the outer side of the rotating magnets 63, the exhaust duct 43 is symmetrically disposed on the side wall of the end of the impact force utilizing box 60 far away from the air inlet duct 24, filtered waste gas enters the impact force utilization box body 60 through the air inlet pipeline 24, the waste gas impacts the fan blades 61, the fan blades 61 drive the rotating shaft 62 to rotate, the rotating shaft 62 drives the magnet carrier 64 to rotate, the magnet carrier 64 drives the rotating magnet 63 to rotate inside the stator coil 42, and when a part of conductors of a closed circuit do cutting magnetic induction line movement, induced current can be generated on the conductors, so that power generation is performed.

As shown in fig. 5, a controller 13 is arranged on the side wall of the scrap recovery box body 12, and the controller 13 is respectively electrically connected with the magnetomotive fixed electromagnet 6, the magnetomotive lifting electromagnet 7, the three-phase coil 25, the electrostatic generator 28, the cooling water-cooling machine 31, the recovery water pump 40, the double-shaft motor 50, the grinding motor 53 and the clamping cylinder 56.

As shown in fig. 3, the energy storage unit 3 is disposed on the upper wall of the base 2, and the energy storage unit 3 is electrically connected to the controller 13 and the stator coil 42, respectively.

When the device is used specifically, in the first embodiment, the height of the clamping frame 15 is adjusted according to the height of an individual, the controller 13 controls the magnetomotive force fixing electromagnet 6 and the magnetomotive force lifting electromagnet 7 to be electrified respectively, the magnetomotive force fixing electromagnet 6 and the magnetomotive force lifting electromagnet 7 are arranged in the same polarity, the magnetomotive force fixing electromagnet 6 pushes the magnetomotive force lifting electromagnet 7 to rise through repulsion force, the magnetomotive force lifting electromagnet 7 drives the lifting platform 10 to slide to rise along the lifting sliding groove 8 through the sliding connecting rod 9, the lifting platform 10 drives the clamping frame 15 to rise through the scrap recovery box body 12 to a specified height, a pump body to be processed is placed on the bearing plate 58, the controller 13 controls the clamping cylinder 56 to be started, the clamping cylinder 56 extends to drive the clamping blocks 57 to clamp and fix the two sides of the pump body, the pump body is fixed on the bearing plate 58, the controller 13 controls the biaxial motor 50 to be started to move the polishing motor 53 to a specified polishing angle, the double-shaft motor 50 drives the walking gear 51 to rotate, the walking gear 51 is meshed with the walking force-borrowing rack 45, the walking gear 51 drives the connecting block 49 to move through the walking force-borrowing rack 45, the connecting block 49 slides along the arc sliding groove 47 through the multi-angle walking sliding rod 48, after the position reaches a designated position, the controller 13 controls the electric telescopic rod 52 to be started, the power end of the electric telescopic rod 52 extends to drive the polishing motor 53 and the polishing head 54 to be close to the surface of the pump body, the polishing head 54 is attached to the surface of the pump body, the controller 13 controls the polishing motor 53 to be started, and the polishing motor 53 drives the polishing head 54 to rotate to polish the surface of the pump body; in the second embodiment, the scraps generated in the grinding process fall onto the scraps filter screen 14 to absorb dust generated in the grinding process, the controller 13 controls the waste gas recovery filter pump 21 to start, the waste gas recovery filter pump 21 pumps the waste gas into the filter pipeline 23 through the exhaust gas suction hose 27 via the exhaust gas suction pipeline 22, the filter pipeline 23 conveys the waste gas into the waste gas impurity filter tower 17, the waste gas enters the unpowered rotary cylinder 18, the controller 13 controls the three-phase coil 25 to be electrified, the unpowered rotary cylinder 18 rotates around the filter pipeline 23 and the unpowered air inlet pipeline 24 under the magnetic field force of the three-phase coil 25 and the power magnet 26, under high-speed rotation, fixed impurities in the waste gas are attached to the inner wall of the unpowered rotary cylinder 18 due to the factor of gravity, the impurities attached to the inner wall of the unpowered rotary cylinder 18 are thrown out of the unpowered rotary cylinder 18 through the impurity throwing port 19, the controller 13 controls the electrostatic generator 28 to start, the electrostatic generator 28 generates electrostatic ions through the power end, which is an electrostatic environment in the exhaust gas impurity filtering tower 17, the electrostatic ions and the grand impurities throwing port 19 enter the unpowered rotary cylinder 18 and are adsorbed on the wire gauze filling layer 29, fine dust in the exhaust gas enters the impact force utilization box 60 from the air inlet pipe 24 after being filtered by the wire gauze filling layer 29, the entering impact force utilizes the gas in the box 60 to impact the fan blades 61, the fan blades 61 drive the rotating shaft 62 to rotate, the rotating shaft 62 drives the rotating magnet 63 to rotate in the stator coil 42 through the magnet carrier 64, and the stator coil 42 transmits the generated induced current to the energy storage unit 3 for storage; in the third embodiment, the grinding tool and the pump body are cooled, the cooling water cooler 31 pumps water in the water storage tank 38 through the water pumping pipeline 34 to cool, the water enters the cold water conveying flexible hose 32 through the water outlet pipeline 33, the water in the cold water conveying flexible hose 32 is sprayed out through the cooling pipeline 35 to cool the grinding tool and the pump body, the cooled water falls into the bottom of the scrap recovery tank 12 after being filtered by the scrap filter screen 14, the filtered water is conveyed into the cooling water return pipeline 37 through the recovery flexible hose 39 by the recovery water pump 40 to be recycled, and water resources are fully utilized; in the fourth embodiment, the position of the pump body on the bearing plate 58 can be changed in the using process, the controller 13 controls the power end of the clamping cylinder 56 at one end of the clamping frame 15 to extend, the controller 13 controls the power end of the clamping cylinder 56 at the other end of the clamping frame 15 to shorten, and the position of the pump body is moved, so that the surface of the pump body is polished in a dead-angle-free moving mode.

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.

Claims (10)

1. The utility model provides an anion absorption formula energy utilization type pump body multidimension degree processing apparatus which characterized in that: comprises a main body supporting mechanism (1), a magnetomotive open type waste scrap collecting and lifting mechanism (5), a centrifugal waste gas impurity electrostatic state medium adsorption mechanism (16), a circulating water resource utilization type cooling mechanism (30), a multi-angle arc state pump body surface walking grinding mechanism (44), a pneumatic translation adjusting and clamping mechanism (55) and a new energy type waste gas power recycling mechanism (59), wherein the main body supporting mechanism (1) comprises a base (2) and an arch structure (4), the arch structure (4) is arranged on one end upper wall of the base (2), the magnetomotive open type waste scrap collecting and lifting mechanism (5) is arranged on one end upper wall of the base (2) close to the arch structure (4), the centrifugal waste gas impurity electrostatic state medium adsorption mechanism (16) is arranged on one end upper wall of the base (2) far away from the magnetomotive open type waste scrap collecting and lifting mechanism (5), circulating water resource utilization type cooling mechanism (30) are located magnetism dynamic formula and are opened type sweeps and collect elevating system (5) and base (2) upper wall between centrifugal waste gas impurity electrostatic state medium adsorption device (16), multi-angle circular arc state pump body surface walking grinding machanism (44) are located on arched door structure (4), pneumatic type translation is adjusted fixture (55) and is located magnetism dynamic formula and open type sweeps and collect elevating system (5) on, new forms of energy type waste gas power recycle mechanism (59) are located and are kept away from circulating water resource utilization type cooling mechanism (30) one side's upper wall.

2. The multi-dimensional processing device for the negative ion adsorption type energy utilization pump body according to claim 1, characterized in that: magnetic power formula opens type sweeps and collects elevating system (5) and includes magnetomotive fixed electromagnet (6), magnetomotive lifting electromagnet (7), lifting sliding groove (8), sliding connection pole (9), elevating platform (10), support (11), sweeps and retrieve box (12), sweeps filter screen (14) and clamping frame (15), arched door structure (4) sets up for the type of falling U, arched door structure (4) both sides inner wall is located to lifting sliding groove (8) symmetry, lifting sliding groove (8) are one end open-ended cavity.

3. The multi-dimensional processing device for the negative ion adsorption type energy utilization pump body according to claim 2, characterized in that: sliding connection pole (9) slide locate in lift sliding tray (8), between sliding connection pole (9) are located in elevating platform (10), elevating platform (10) upper wall is located to support (11) symmetry, sweeps is retrieved box (12) and is located between one side that elevating platform (10) were kept away from in support (11), sweeps is retrieved box (12) and is upper end open-ended cavity, sweeps recovery box (12) inner wall is located in sweeps filter screen (14), sweeps is retrieved box (12) upper wall in centre gripping frame (15) are located, elevating platform (10) diapire is located in magnetic power lift electro-magnet (7), base (2) upper wall below elevating platform (10) is located in magnetic power fixed electro-magnet (6).

4. The multi-dimensional processing device for the negative ion adsorption type energy utilization pump body according to claim 3, wherein: the centrifugal waste gas impurity electrostatic state medium adsorption mechanism (16) comprises a waste gas impurity filtering tower (17), an unpowered rotary cylinder body (18), an impurity throwing outlet (19), a fixing frame (20), a waste gas recovery filtering pump (21), an air extraction pipeline (22), a filtering pipeline (23), an air inlet pipeline (24), a three-phase coil (25), a power magnet (26), a waste gas suction hose (27), an electrostatic generator (28) and a wire mesh filling layer (29), wherein the fixing frame (20) is symmetrically arranged at two sides of an arch structure (4), the waste gas impurity filtering tower (17) is arranged between one sides of the fixing frame (20) far away from the arch structure (4), the waste gas recovery filtering pump (21) is arranged on the upper wall of the waste gas impurity filtering tower (17), the air extraction pipeline (22) is arranged at the power input end of the waste gas recovery filtering pump (21), and the waste gas suction hose (27) is communicated between a waste scrap recovery box body (12) and the air extraction pipeline (22), waste gas impurity filtering tower (17) diapire is located in admission line (24) intercommunication, unpowered rotatory barrel (18) rotate locate between admission line (24) and pumping line (22), pumping line (22) and admission line (24) communicate respectively and locate unpowered rotatory barrel (18), unpowered rotatory barrel (18) bottom is located in wire netting filling layer (29).

5. The multi-dimensional processing device for the negative ion adsorption type energy utilization pump body according to claim 4, wherein: pneumatic type translation adjustment fixture (55) include die clamping cylinder (56), add and hold piece (57) and loading board (58), die clamping cylinder (56) symmetry is located centre gripping frame (15) both sides, and die clamping cylinder (56) power end runs through centre gripping frame (15) lateral wall and locates between centre gripping frame (15) inner wall, add and hold piece (57) and locate die clamping cylinder (56) power end, die clamping cylinder (56) set up relatively, clamping frame (15) inner wall is located in loading board (58).

6. The multi-dimensional processing device for the negative ion adsorption type energy utilization pump body according to claim 5, wherein: impurity gets rid of export (19) multiunit and locates unpowered rotatory barrel (18) lateral wall, filtering duct (23) intercommunication is located between exhaust impurity filter tower (17) upper wall and exhaust recovery filter pump (21) power take off end, unpowered rotatory barrel (18) outside is located in admission line (24), exhaust impurity filter tower (17) both sides inner wall is located to power magnet (26) symmetry, power magnet (26) and three-phase coil (25) level set up, exhaust impurity filter tower (17) lateral wall is located in electrostatic generator (28), and electrostatic generator (28) power end runs through exhaust impurity filter tower (17) and locates inside exhaust impurity filter tower (17).

7. The multi-dimensional processing device for the negative ion adsorption type energy utilization pump body according to claim 6, wherein: the circulating water resource utilization type cooling mechanism (30) comprises a cooling water cooler (31), a cold water conveying telescopic hose (32), a water outlet pipeline (33), a water pumping pipeline (34), a cooling pipeline (35), a pipeline clamp (36), a cooling water return pipeline (37), a water storage tank body (38), a recovery telescopic hose (39), a recovery water pump (40) and a water inlet pipeline (41), wherein the water storage tank body (38) is arranged on the upper wall of the base (2) on one side of the arch door structure (4), the cooling water cooler (31) is arranged on the upper wall of the water storage tank body (38), the water pumping pipeline (34) is communicated and arranged between the power input end of the cooling water cooler (31) and the upper wall of the water storage tank body (38), the water outlet pipeline (33) is arranged at the power output end of the cooling water cooler (31), the pipeline clamp (36) is arranged on the upper wall of the clamping frame (15), and the cooling pipeline (35) is arranged on the pipeline clamp (36), the utility model discloses a cooling water cooling system, including cooling water conveying expansion hose (32), water storage tank (38) upper wall, inlet channel (41) intercommunication are located between water storage tank (38) upper wall and recovery water pump (40) power take off end of cooling water-cooled machine (31) one side, cooling water return line (37) are located and are retrieved water pump (40) power input end, retrieve expansion hose (39) intercommunication and locate between sweeps recovery tank (12) diapire and cooling water return line (37).

8. The multi-dimensional processing device for the negative ion adsorption type energy utilization pump body according to claim 7, wherein: the new energy type waste gas power recycling mechanism (59) comprises an impact force utilization box body (60), fan blades (61), a rotating shaft (62), a rotating magnet (63), a magnet carrier (64), a stator coil (42) and an exhaust pipeline (43), wherein the impact force utilization box body (60) is arranged on the upper wall of a base (2) on one side, away from a water storage box body (38), of a waste gas impurity filtering tower (17), an air inlet pipeline (24) is communicated with one end, away from a unpowered rotating cylinder body (18), of the air inlet pipeline (24) and is arranged in the impact force utilization box body (60), the rotating shaft (62) is rotatably arranged on the inner wall on one side, away from the impact force utilization box body (24), of the magnet carrier (64) is arranged on the outer side of the rotating magnet carrier (64), a plurality of groups of rotating magnets (63) are arranged on the outer side, the rotating magnets (63) which are adjacently arranged are heteropolars, the stator coil (42) is arranged on the inner wall of the impact force utilization box body (60) on the outer side of the rotating magnet carrier (63), the exhaust pipelines (43) are symmetrically arranged on the side wall of one end, far away from the air inlet pipeline (24), of the impact force utilization box body (60).

9. The multi-dimensional processing device for the negative ion adsorption type energy utilization pump body according to claim 8, wherein: the multi-angle arc-shaped pump body surface walking polishing mechanism (44) comprises a walking force-borrowing rack (45), an arc-shaped through groove (46), an arc-shaped sliding groove (47), a multi-angle walking sliding rod (48), a connecting block (49), a double-shaft motor (50), a walking gear (51), an electric telescopic rod (52), a polishing motor (53) and a polishing head (54), wherein the arc-shaped through groove (46) is formed in the upper wall of an arch door structure (4), the arc-shaped through groove (46) is arranged in a run-through manner, the arc-shaped sliding groove (47) is symmetrically arranged on the inner walls of two sides of the arc-shaped through groove (46), the arc-shaped through groove (46) is oppositely arranged, the arc-shaped through groove (46) is a cavity with one open end, the multi-angle walking sliding rod (48) is slidably arranged in the arc-shaped sliding groove (47), the connecting block (49) is arranged between the multi-angle walking sliding rod (48), and the double-shaft motor (50) is arranged on the upper wall of the connecting block (49), the power take off of biax motor (50) both sides is located to walking gear (51) symmetry, the arch structure (4) upper wall that the arc type led to groove (46) both sides is located to power rack (45) symmetry is borrowed in the walking, power rack (45) mesh is borrowed with the walking in walking gear (51), connecting block (49) diapire is located in electric telescopic handle (52), electric telescopic handle (52) is located in grinding motor (53) one side of keeping away from connecting block (49), grinding head (54) are located grinding motor (53) power end.

10. The multi-dimensional processing device for the negative ion adsorption type energy utilization pump body according to claim 9, wherein: the scrap recovery box body (12) lateral wall is equipped with controller (13), controller (13) respectively with magnetic power fixed electromagnet (6), magnetic power lift electromagnet (7), three-phase coil (25), electrostatic generator (28), cooling water-cooling machine (31), recovery water pump (40), double-shaft motor (50), grinding motor (53) and die clamping cylinder (56) electric connection, base (2) upper wall is equipped with energy storage unit (3), energy storage unit (3) respectively with controller (13) and stator coil (42) electric connection.

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