CN116749358B - Carbon electrode inner and outer integrated machining center - Google Patents

Abstract

The invention discloses an inner and outer integrated machining center of a carbon electrode, which relates to the technical field of carbon electrode machining and comprises the following steps: machine tool, external machining assembly, internal machining assembly, moving assembly and cleaning assembly. When the dust collection device is used, an external power supply of the controller is turned on, the industrial dust collection fan is started through the controller, dust generated during internal and external processing is sucked into the fixed pipe through the plurality of conical dust collection covers, then the air with the dust is sequentially pumped into the U-shaped pipe and the dust collection pipe and finally discharged into the needled felt dust collection bag, the needled felt dust collection bag can efficiently filter particles and dust in the air, after the internal and external processing of carbon electrode materials is finished, the controller controls the servo motor and the stepping motor to start, the servo motor drives the rotating shaft to rotate, then drives the cleaning roller and the antistatic dust collection brush to rotate, and simultaneously the carbon electrode materials are driven by the stepping motor to rotate, so that the outer surface of the carbon electrode materials is cleaned.

Description

Carbon electrode inner and outer integrated machining center

Technical Field

The invention relates to the technical field of carbon electrode machining, in particular to an inner and outer integrated machining center of a carbon electrode.

Background

Carbon electrodes are an electrode material used in electrolytic cells and electrochemical reactions, and are typically made of high purity natural or synthetic graphite. It is mainly characterized by good conductivity, thermal stability and chemical stability, can bear severe conditions such as high temperature, high pressure and the like, and has higher corrosion resistance and mechanical strength. The preparation process of the carbon electrode is generally divided into two steps of carbonization and sintering, wherein the carbonization is to heat raw material graphite at high temperature to enable the raw material graphite to generate carbonization reaction to form high-purity carbon material, and the sintering is to heat the carbonized carbon material again to enable the carbonized carbon material to be solidified and formed to prepare the electrode. The carbon electrode is widely applied to the fields of aluminum electrolysis, chlor-alkali electrolysis, copper, zinc, nickel and other metal production, high-energy density batteries, super capacitors, fuel cells and the like. In the field of environmental protection, the carbon electrode can also be used in applications such as wastewater treatment, electrochemical pollutant removal and the like.

In the prior art, a traditional carbon electrode is generally composed of a graphite plate and an electrode column, the two sides of the graphite plate are turned through a drill bit to be processed into electrode holes, then the electrode column is screwed into the electrode holes on the two sides of the graphite plate, after the graphite plate in the carbon electrode is internally and externally processed by the existing carbon electrode processing center, more dust can be generated on the outer surface of the graphite plate, if the graphite plate is not cleaned timely, the dust covered on the outer surface is easy to absorb oxygen in air, so that the surface of the carbon electrode is oxidized, and the performance and the service life of the carbon electrode are affected.

We have therefore proposed a carbon electrode inner and outer integrated machining center in order to solve the problems set forth above.

Disclosure of Invention

The invention aims to provide an inner and outer integrated machining center for a carbon electrode, which is used for solving the problems that after the carbon electrode is machined in the inner and outer integrated machining center for the carbon electrode, the outer surface of a graphite plate can generate more dust to cover the outer surface, and if the carbon electrode is not cleaned in time, the dust easily absorbs oxygen in the air, so that the surface of the carbon electrode is oxidized, and the performance and the service life of the carbon electrode are affected.

In order to achieve the above purpose, the present invention provides the following technical solutions: carbon electrode inside and outside integrative machining center includes: the dust collection device comprises a machine tool, an external machining assembly, an internal machining assembly, a moving assembly and a cleaning assembly, wherein the dust collection assembly is fixedly arranged on the outer surface of one side of the machine tool, and a controller is arranged on the front surface, close to the other side, of the machine tool; the cleaning assembly comprises a servo motor, a rotating shaft is fixedly arranged at the output end of the servo motor, a cleaning roller is fixedly arranged at the center of the outer surface of the rotating shaft, and an anti-static ash cleaning brush is fixedly arranged on the outer surface of the cleaning roller; the dust collection assembly comprises a support plate, an industrial dust collection fan is fixedly mounted at the top of the support plate, a dust collection pipe is connected to the input end of the industrial dust collection fan through a flange plate, a needled felt dust collection bag is arranged at the output end of the industrial dust collection fan, a U-shaped pipe is fixedly connected to one end of the dust collection pipe, fixing pipes are fixedly mounted at two ends of the U-shaped pipe, and a plurality of conical dust collection covers are fixedly communicated with the outer surfaces of the fixing pipes.

Preferably, the front surface of lathe is provided with the protection subassembly, the opposite side surface of lathe is provided with quantitative feeding subassembly, the protection subassembly includes four L templates, two of them the equal fixed mounting of inner wall of L template has first hydraulic stem, and two of them the equal fixed mounting of inner wall of L template has the second hydraulic stem, two the equal fixed mounting of one end of first hydraulic stem and the one end of two second hydraulic stems have the fixed block, two of them the equal fixed mounting of surface of fixed block has wear-resisting baffle, two of them the equal fixed mounting of surface of fixed block has the protection baffle.

Preferably, four L-shaped plates are equally divided into two groups, the outer surfaces of the two groups of L-shaped plates are respectively and fixedly arranged on the front surface and the rear surface of a machine tool, the front surface and the rear surface of the machine tool, which are close to the other side, are respectively provided with first sliding holes, the front surface and the rear surface of the machine tool, which are close to one side, are respectively and movably embedded in the two first sliding holes, the outer surfaces of the two wear-resistant baffles are respectively and movably embedded in the two second sliding holes, the quantitative feeding assembly comprises two fixing plates, and the outer surface of one fixing plate is fixedly provided with a first motor through an auxiliary block.

Preferably, the movable assembly comprises a U-shaped plate, two connecting rods are movably embedded in the U-shaped plate, two receiving rollers are fixedly arranged on the outer surfaces of the connecting rods, leather wheels are fixedly arranged at one ends of the connecting rods, belts are movably sleeved on the outer surfaces of the leather wheels, a stepping motor is fixedly arranged on the front surface of the U-shaped plate through an auxiliary plate, the output end of the stepping motor is fixedly connected with the front surface of one of the leather wheels, and a multistage electric push rod is fixedly arranged at the center of the bottom of the U-shaped plate.

Preferably, the U-shaped plate is close to the top of front surface and rear surface and all fixedly mounted with arc baffle, two the both ends of connecting rod are respectively movable to run through to the front surface and the rear surface of U-shaped plate, the bottom fixed mounting of multistage electric putter is in the center department of the inside bottom of lathe, the dust cover is installed through the screw to the front surface of U-shaped plate, the bottom that the U-shaped plate is close to front surface and rear surface is all fixedly mounted with multisection telescopic link, two the surface of multisection telescopic link all is provided with the spring, two the bottom of multisection telescopic link and the one end of two springs are fixed mounting respectively in the inside bottom that is close to front surface wall and rear surface wall of lathe.

Preferably, the external processing subassembly includes two bull sticks, two the equal fixed mounting of surface of bull stick has outside grinding roller, two the equal fixed mounting of one end of bull stick has the gear, two the surface meshing of gear is connected with the tooth area, the lathe is close to the front surface of bottom and is installed several words mounting panel through the bolt, the inside fixed mounting of several words mounting panel has the second motor, the output of second motor and the front surface fixed connection of one of them gear, two the one end of bull stick all activity runs through to the front surface of lathe, two the other end of bull stick all activity inlays the back table wall of establishing near the bottom at the lathe.

Preferably, the inside processing subassembly includes biax motor, two equal fixed mounting of output of biax motor have the lead screw, two the surface that the lead screw is close to one end is equal the thread bush and is equipped with L type frame, two the equal fixed mounting in bottom of L type frame inside has the third motor, two the output of third motor all is provided with the toper screw bit, rectangular slide hole has all been seted up to the front surface and the rear surface of lathe, two the surface that the L type frame is close to the bottom is movable respectively to be inlayed and is established the inside at two rectangular slide holes.

Preferably, the support slide hole has all been seted up to two the surface of L type frame, two the inside of support slide hole is all movably inlayed and is equipped with the bracing piece, two the one end of bracing piece is fixed mounting respectively at the lathe front surface and the back surface that are close to the top, two the equal movable sleeve of surface of lead screw is equipped with a plurality of supporting shoe, a plurality of the bottom of supporting shoe is fixed mounting at the top of lathe, the surface fixed mounting of biax motor is in the center department at lathe top, the one end of dust absorption pipe is fixed to run through to the inside of lathe, two the both ends of fixed pipe are fixed respectively at the lathe front surface wall and the back surface wall that is close to both sides.

Preferably, the pivot is close to the equal movable sleeve of surface at both ends and is equipped with the gusset plate, two the equal fixed mounting in the inside top of lathe in top of gusset plate, servo motor's surface is close to the rear surface of bottom at one of them gusset plate through connecting plate fixed mounting, the surface of backup pad is through strengthening rib fixed mounting at the one side surface that the lathe is close to the top, one side surface fixed mounting of backup pad has first baffle, the backup pad is close to the top fixed mounting of front surface and has the second baffle.

Preferably, the output end fixed mounting of first motor has the fixed axle, the center department fixed mounting of fixed axle surface has a fixed section of thick bamboo, a plurality of quantitative boards are installed to the surface equidistance of fixed section of thick bamboo, the feed opening has been seted up to one side surface of lathe, the inside bottom fixed mounting of feed opening has the slope flitch, the feed opening has been seted up to the opposite side surface of lathe, the inside bottom fixed mounting of feed opening has the slope flitch, two fixed plate is close to the front surface and the rear surface of bottom relative one side fixed mounting respectively at the slope flitch.

Compared with the prior art, the invention has the beneficial effects that:

1. when the dust collection device is used, an external power supply of the controller is turned on, the industrial dust collection fan is started through the controller, dust generated during internal and external processing is sucked into the fixed pipe through the plurality of conical dust collection covers, then the air with the dust is pumped into the U-shaped pipe and the dust collection pipe in sequence, finally the air is discharged into the needled felt dust collection bag, the needled felt dust collection bag can efficiently filter particles and dust in the air, and finally clean air is discharged, so that the dust collection effect is achieved, pollution of the dust to the working environment is reduced, after the internal and external processing of the carbon electrode materials is finished, the controller controls the servo motor and the stepping motor to start, the output end of the servo motor drives the rotating shaft to rotate, then drives the cleaning roller to rotate, further drives the anti-static dust collection brush to clean the outer surface of the carbon electrode materials, meanwhile, the output end of the stepping motor drives one leather belt to rotate, the other leather wheel is further drives the two connecting rods to rotate in the same direction, and drives the two material collection rollers to rotate, so that the carbon electrode materials rotate, clean the surfaces of the carbon electrode materials are cleaned through the anti-static brush, the dust collection device is cleaned, and the dust collection assembly is cleaned, and the dust collection effect is achieved.

2. When the automatic feeding device is used, the two first hydraulic rods are controlled by the controller to start simultaneously, the two wear-resistant baffles are driven to move in the opposite directions, then the first motor is controlled by the controller to start, the fixed shaft is driven to rotate, then the fixed cylinder and the quantitative plate are driven to rotate ninety degrees, the carbon electrode materials below the fixed shaft are driven to fall and roll to the tops of the two receiving rollers, under the limit of the two wear-resistant baffles, the carbon electrode materials are prevented from falling from the tops of the receiving rollers, after the carbon electrode materials below the fixed shaft are pushed onto the moving assembly, the carbon electrode materials above the fixed shaft are stirred to the position below by the quantitative plate and limited, automatic downward rolling is prevented, the quantitative feeding effect is achieved, one carbon electrode material is conveyed at a time, and internal and external processing is facilitated.

3. The external machining assembly and the internal machining assembly are used for carrying out internal and external integrated machining on the carbon electrode material, the multi-stage electric push rod is started, the U-shaped plate is pulled to move downwards, the two connecting rods and the two material receiving rollers are driven to move downwards, the carbon electrode material is driven to move downwards together and fall between the two external grinding rollers, the two external grinding rollers are contacted with each other, then the second motor is started, one gear is driven to rotate, the toothed belt connected with the gear is meshed with the gear to drive the other gear to rotate, so that the two rotating rods simultaneously rotate in the same direction, the two external grinding rollers are further driven to rotate, the external grinding machining is carried out on the carbon electrode material, after the external machining is finished, the multi-stage electric push rod is started again, the polished carbon electrode material is pushed upwards to the original position, the two output ends of the two double-shaft motor are driven to rotate simultaneously through the controller to drive the two L-shaped frames to move in the opposite directions, and the two third motors are driven to move relatively, the two conical threaded drills move to the two ends of the carbon electrode material, and the two conical threaded drills are driven by the two third motors to drive the two conical motors to simultaneously cut the two ends of the internal threaded drills to machine the internal threaded holes of the carbon electrode material.

4. Through setting up the protection subassembly and being convenient for carry out spacingly to the carbon electrode material, start two first hydraulic stems simultaneously, promote two wear-resisting baffle relative movement, two wear-resisting baffle are located one side of carbon electrode material this moment, start the second hydraulic stem, promote two protection baffle relative direction movements, two protection baffle are located the opposite side of carbon electrode material this moment, thereby carry out spacingly to the both sides of carbon electrode material, under the effect of two arc baffles, carry out spacingly to the both ends of carbon electrode material, after the inside and outside processing and surperficial deashing are accomplished to the carbon electrode material, two first hydraulic stems start again, the pulling two wear-resisting baffles reset, one side of carbon electrode material loses spacingly, two second hydraulic stems resume work, continue to promote two protection baffle relative movement, make two protection baffle arc protruding portions contact with the carbon electrode material, and promote the carbon electrode material to roll to the slope blanking board on from receiving cylinder, be convenient for carry out the unloading.

Drawings

FIG. 1 is a front perspective view of an integrated machining center for both inner and outer carbon electrodes of the present invention;

FIG. 2 is a rear perspective view of an integrated machining center for both inner and outer carbon electrodes of the present invention;

FIG. 3 is a cross-sectional expanded perspective view of the carbon electrode inner and outer integrated machining center of the present invention;

FIG. 4 is a cross-sectional expanded perspective view of the structure of a machine tool in the carbon electrode inner and outer integrated machining center of the present invention;

FIG. 5 is a structural expanded perspective view of a quantitative feeding assembly in an integrated machining center inside and outside a carbon electrode according to the present invention;

FIG. 6 is a structural expanded perspective view of an outer tooling assembly in an inner and outer integrated machining center for carbon electrodes in accordance with the present invention;

FIG. 7 is a structural expanded perspective view of a protective assembly in a carbon electrode inner and outer integrated machining center according to the present invention;

FIG. 8 is a structural expanded perspective view of a cleaning assembly in an integrated machining center for both the inside and outside of a carbon electrode in accordance with the present invention;

FIG. 9 is a structural exploded perspective view of a dust collection assembly in a carbon electrode inner and outer integrated machining center of the present invention;

FIG. 10 is a structurally expanded perspective view of a mobile assembly in an integrated machining center for both inner and outer carbon electrodes in accordance with the present invention;

fig. 11 is an enlarged perspective view at a in fig. 10;

FIG. 12 is a structural expanded perspective view of an internal processing assembly in a carbon electrode internal and external integrated processing center according to the present invention;

FIG. 13 is a structural expanded perspective view of a tapered thread drill in an integrated machining center for both the inside and outside of a carbon electrode according to the present invention;

FIG. 14 is a cross-sectional, expanded perspective view of another angular configuration of a machine tool in a carbon electrode internal and external integrated machining center of the present invention.

In the figure: 1. a machine tool; 2. an external tooling assembly; 201. a rotating rod; 202. an external grinding roller; 203. a gear; 204. a dental tape; 205. a second motor; 206. a mounting plate in a shape of a Chinese character 'ji'; 3. a protective assembly; 301. an L-shaped plate; 302. a first hydraulic lever; 303. a second hydraulic lever; 304. wear-resistant baffle plates; 305. a protective baffle; 306. a fixed block; 4. an internal processing assembly; 401. a biaxial motor; 402. a screw rod; 403. an L-shaped frame; 404. a third motor; 405. a tapered thread drill bit; 406. a support rod; 407. a support block; 408. a support slide hole; 5. a dust collection assembly; 501. a support plate; 502. an industrial dust collection fan; 503. needling a felt dust removal bag; 504. a first separator; 505. a second separator; 506. a dust collection pipe; 507. a U-shaped tube; 508. a fixed tube; 509. a conical dust hood; 6. quantitative feeding components; 601. a fixing plate; 602. a first motor; 603. a fixed shaft; 604. a fixed cylinder; 605. a metering plate; 7. a controller; 8. cleaning the assembly; 801. a servo motor; 802. a rotating shaft; 803. cleaning a roller; 804. an antistatic ash removing brush; 805. a reinforcing plate; 9. a moving assembly; 901. a U-shaped plate; 902. a connecting rod; 903. a receiving roller; 904. a multi-stage electric push rod; 905. a multi-section telescopic rod; 906. a spring; 907. a dust cover; 908. an arc baffle; 909. a leather wheel; 910. a belt; 911. a stepping motor; 10. tilting the blanking plate; 11. tilting the feeding plate; 12. a feed opening; 13. a feeding port; 14. a second slide hole; 15. rectangular slide holes; 16. a first slide hole.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1 to 14, the present invention provides a technical solution: carbon electrode inside and outside integrative machining center includes: the dust collection device comprises a machine tool 1, an external machining assembly 2, an internal machining assembly 4, a moving assembly 9 and a cleaning assembly 8, wherein a dust collection assembly 5 is fixedly arranged on the outer surface of one side of the machine tool 1, and a controller 7 is arranged on the front surface, close to the other side, of the machine tool 1; the cleaning assembly 8 comprises a servo motor 801, a rotating shaft 802 is fixedly arranged at the output end of the servo motor 801, a cleaning roller 803 is fixedly arranged at the center of the outer surface of the rotating shaft 802, and an anti-static ash cleaning brush 804 is fixedly arranged on the outer surface of the cleaning roller 803; the dust collection assembly 5 comprises a support plate 501, an industrial dust collection fan 502 is fixedly arranged at the top of the support plate 501, a dust collection pipe 506 is connected to the input end of the industrial dust collection fan 502 through a flange plate, a needled felt dust collection bag 503 is arranged at the output end of the industrial dust collection fan 502, a U-shaped pipe 507 is fixedly connected to one end of the dust collection pipe 506, fixing pipes 508 are fixedly arranged at two ends of the U-shaped pipe 507, and a plurality of conical dust collection covers 509 are fixedly communicated with the outer surfaces of the two fixing pipes 508.

Meanwhile, as shown in fig. 1-4, 7 and 14, the front surface of the machine tool 1 is provided with a protection component 3, the outer surface of the other side of the machine tool 1 is provided with a quantitative feeding component 6, the protection component 3 comprises four L-shaped plates 301, wherein the inner walls of the two L-shaped plates 301 are fixedly provided with first hydraulic rods 302, the inner walls of the other two L-shaped plates 301 are fixedly provided with second hydraulic rods 303, one ends of the two first hydraulic rods 302 and one ends of the two second hydraulic rods 303 are fixedly provided with fixed blocks 306, the outer surfaces of the two fixed blocks 306 are fixedly provided with wear-resistant baffles 304, the outer surfaces of the other two fixed blocks 306 are fixedly provided with protection baffles 305, the two first hydraulic rods 302 are started to push the two wear-resistant baffles 304 to move relatively, the two second hydraulic rods 303 are started to push the two protection baffles 305 to move relatively, the two wear-resistant baffles 304 and the two protection baffles 305 are respectively located on two sides of a carbon electrode material to limit the carbon electrode material, and the carbon electrode material is prevented from falling from the material receiving roller 903.

According to the figures 1-5, 7 and 14, four L-shaped plates 301 are equally divided into two groups, the outer surfaces of the two groups of L-shaped plates 301 are fixedly mounted on the front surface and the rear surface of the machine tool 1 respectively, the front surface and the rear surface of the machine tool 1 close to the other side are provided with first sliding holes 16, the front surface and the rear surface of the machine tool 1 close to one side are provided with second sliding holes 14 respectively, the outer surfaces of two wear-resistant baffles 304 are movably embedded in the interiors of the two first sliding holes 16 respectively, the outer surfaces of two protective baffles 305 are movably embedded in the interiors of the two second sliding holes 14 respectively, the quantitative feeding assembly 6 comprises two fixing plates 601, the outer surface of one fixing plate 601 is fixedly provided with a first motor 602 through an auxiliary block, the two first hydraulic rods 302 and the two second hydraulic rods 303 are conveniently mounted through the four L-shaped plates 301, and the wear-resistant baffles 304 and the protective baffles 305 slide inside the machine tool 1 smoothly and conveniently.

According to fig. 3 and 10-11, the moving assembly 9 includes a U-shaped plate 901, two connecting rods 902 are movably embedded in the U-shaped plate 901, two receiving rollers 903 are fixedly installed on the outer surfaces of the two connecting rods 902, leather wheels 909 are fixedly installed at one ends of the two connecting rods 902, belts 910 are movably sleeved on the outer surfaces of the two leather wheels 909, a stepping motor 911 is fixedly installed on the front surface of the U-shaped plate 901 through an auxiliary plate, the output end of the stepping motor 911 is fixedly connected with the front surface of one leather wheel 909, a multi-stage electric push rod 904 is fixedly installed at the center of the bottom of the U-shaped plate 901, one leather wheel 909 is driven to rotate through starting the stepping motor 911, then the belts 910 are driven to rotate, the other leather wheel 909 is further driven to rotate, the two connecting rods 902 are simultaneously rotated in the same direction, the two receiving rollers 903 are driven to rotate, and accordingly carbon electrode materials are driven to rotate on the outer surfaces of the two receiving rollers 903, and the U-shaped plate 901 is conveniently driven to move up and down through the multi-stage electric push rod 904.

According to the figures 1-4, 10-11 and 14, the top of the U-shaped plate 901, which is close to the front surface and the rear surface, is fixedly provided with an arc baffle 908, two ends of two connecting rods 902 respectively movably penetrate through the front surface and the rear surface of the U-shaped plate 901, the bottom end of a multistage electric push rod 904 is fixedly provided with a dust cover 907 through screws, the front surface of the U-shaped plate 901 is fixedly provided with a plurality of telescopic rods 905 at the bottoms of the U-shaped plate 901, which are close to the front surface and the rear surface, the outer surfaces of the two telescopic rods 905 are respectively provided with a spring 906, the bottoms of the two telescopic rods 905 and one ends of the two springs 906 are respectively fixedly provided at the bottoms of the front surface and the rear surface, which are close to the front surface and the rear surface of the machine tool 1, the two ends of the carbon electrode materials are conveniently limited through the two arc baffles 908, the position deviation is prevented, the stepping motor 911 and the two leather wheels 909 are protected through the dust cover 907, the multistage electric push rod 904 is conveniently pushed by the multistage electric push rod 904 to move stably and the two telescopic rods 905 under the support of the two springs 906, and the smooth support 905 is stably moved upwards, and the stability of the support is increased.

According to fig. 1-3, fig. 6 and fig. 14, the external processing assembly 2 comprises two rotating rods 201, external grinding rollers 202 are fixedly installed on the outer surfaces of the two rotating rods 201, gears 203 are fixedly installed at one ends of the two rotating rods 201, toothed belts 204 are connected to the outer surfaces of the two gears 203 in a meshed mode, a Chinese character 'ji' shaped mounting plate 206 is installed on the front surface of the machine tool 1, which is close to the bottom, through bolts, a second motor 205 is fixedly installed in the Chinese character 'ji' shaped mounting plate 206, the output end of the second motor 205 is fixedly connected with the front surface of one of the gears 203, one ends of the two rotating rods 201 are movably penetrated to the front surface of the machine tool 1, the other ends of the two rotating rods 201 are movably embedded in the rear surface wall of the machine tool 1, which is close to the bottom, one of the two rotating rods 203 is driven to rotate through starting the second motor 205, the toothed belts 204 connected with the two gears 203 are simultaneously rotated, the other gears 203 are further driven to rotate, and accordingly the two rotating rods 201 are simultaneously rotated in the same direction, the two external grinding rollers 202 are further driven to rotate, and the carbon electrode materials are externally processed.

According to the figures 1-4, 12-13 and 14, the internal machining component 4 comprises a double-shaft motor 401, two output ends of the double-shaft motor 401 are fixedly provided with screw rods 402, the outer surfaces of the two screw rods 402 close to one end are respectively sheathed with L-shaped frames 403, the bottoms of the interiors of the two L-shaped frames 403 are fixedly provided with third motors 404, the output ends of the two third motors 404 are respectively provided with a conical screw bit 405, the front surface and the rear surface of the machine tool 1 are respectively provided with a rectangular slide hole 15, the outer surfaces of the two L-shaped frames 403 close to the bottoms are respectively movably embedded in the interiors of the two rectangular slide holes 15, the two output ends of the double-shaft motor 401 are controlled by a controller 7 to drive the two screw rods 402 to rotate simultaneously, under the limit of the two rectangular slide holes 15, the two L-shaped frames 403 are driven to move relatively in the same direction, the two conical screw bits 405 are driven to move to the two ends of a carbon electrode material, and the two conical screw bits 405 are driven by the output ends of the two third motors to drive the two conical screw bits 404 to machine the two conical screw bits 405, so that the two electrode material inside the two electrode material.

According to the embodiments shown in fig. 1-4, fig. 9, fig. 12 and fig. 14, the outer surfaces of the two L-shaped frames 403 are provided with support slide holes 408, the inside of the two support slide holes 408 are movably embedded with support rods 406, one ends of the two support rods 406 are respectively and fixedly mounted on the front surface and the rear surface of the machine tool 1 near the top, the outer surfaces of the two screw rods 402 are movably sleeved with a plurality of support blocks 407, the bottoms of the plurality of support blocks 407 are respectively and fixedly mounted on the top of the machine tool 1, the outer surface of the double-shaft motor 401 is fixedly mounted at the center of the top of the machine tool 1, one end of the dust suction pipe 506 is fixedly penetrated into the machine tool 1, and two ends of the two fixing pipes 508 are respectively fixed on the front surface wall and the rear surface wall of the machine tool 1 near two sides, so that the two L-shaped frames 403 are more stable during moving and increase stability, and the screw rods 402 are mounted and supported by the plurality of support blocks 407.

According to the figures 1-4, 8-9 and 14, the outer surfaces of the rotating shaft 802 close to two ends are movably sleeved with reinforcing plates 805, the tops of the two reinforcing plates 805 are fixedly mounted on the top of the machine tool 1, the outer surface of the servo motor 801 is fixedly mounted on the rear surface of one reinforcing plate 805 close to the bottom through a connecting plate, the outer surface of the supporting plate 501 is fixedly mounted on the outer surface of one side of the machine tool 1 close to the top through a reinforcing rib, a first partition plate 504 is fixedly mounted on the outer surface of one side of the supporting plate 501, a second partition plate 505 is fixedly mounted on the top of the supporting plate 501 close to the front surface, and the rotating shaft 802, the servo motor 801, the cleaning roller 803 and the anti-static ash brush 804 are conveniently mounted through the two reinforcing plates 805, and the needlefelt dust bag 503 is conveniently protected through the first partition plate 504 and the second partition plate 505.

According to the figures 1-5 and 14, the fixed axle 603 is fixedly arranged at the output end of the first motor 602, the fixed barrel 604 is fixedly arranged at the center of the outer surface of the fixed axle 603, the fixed barrels 604 are provided with a plurality of quantitative plates 605 at equal intervals on the outer surface, the blanking opening 12 is arranged on the outer surface of one side of the machine tool 1, the inclined blanking plate 10 is fixedly arranged at the bottom of the inside of the blanking opening 12, the feeding opening 13 is arranged on the outer surface of the other side of the machine tool 1, the inclined feeding plate 11 is fixedly arranged at the bottom of the inside of the feeding opening 13, two fixed plates 601 are respectively fixedly arranged on the front surface and the rear surface of the inclined feeding plate 11 near the opposite sides of the bottom, feeding and blanking are facilitated through the inclined feeding plate 11 and the inclined blanking plate 10, the first motor 602 is started to drive the fixed axle 603 to rotate, then the fixed barrels 604 and the quantitative plates 605 are driven to rotate, the carbon electrode materials below are stirred into the machine tool 1, the carbon electrode materials above are stirred into the lower position through the corresponding quantitative plates 605, automatic downward rolling is prevented, the automatic downward rolling is realized, the effect is achieved, and the inner and outer electrode materials are better processed through one-time conveying.

The whole mechanism achieves the following effects: when in use, the second motor 205, the first hydraulic rod 302, the second hydraulic rod 303, the double-shaft motor 401, the third motor 404, the industrial dust suction fan 502, the first motor 602, the servo motor 801, the multi-stage electric push rod 904 and the stepping motor 911 are electrically connected with the controller 7, the moving assembly 9 is positioned between the two external grinding rollers 202, the width of the outer surface of the U-shaped plate 901 is smaller than the width between the two external grinding rollers 202, when not in use, the U-shaped plate 901 is positioned above the two external grinding rollers 202, the external power supply of the controller 7 is turned on, the two first hydraulic rods 302 are controlled to be started simultaneously through the controller 7, the two wear-resistant baffles 304 are pushed to move in the opposite directions inside the two first sliding holes 16 respectively, when the corresponding two fixed blocks 306 are respectively contacted with the front surface and the rear surface of the machine tool 1, the two first hydraulic rods 302 are suspended for a period of time, then the first motor 602 is controlled by the controller 7 to start, the rotation path of the first motor 602 is set in advance, after ninety degrees of rotation, the rotation of the fixed shaft 603 is driven by the output end of the first motor 602, then the fixed shaft 604 and the quantitative plate 605 are driven to rotate ninety degrees, along with the rotation of the quantitative plate 605, the lower carbon electrode material is pushed to roll downwards along the inclined surface of the inclined feeding plate 11 and fall to the top of the two material receiving rollers 903, at the moment, the two wear-resistant baffles 304 are positioned at one side of the carbon electrode material, under the limit blocking of the two wear-resistant baffles 304, the carbon electrode material is prevented from rolling onto the inclined blanking plate 10 from the top of the material receiving rollers 903, the internal and external processing operation of the carbon electrode material is affected, after the lower carbon electrode material is pushed onto the moving assembly 9, the upper carbon electrode material is pushed to the lower position by the quantitative plate 605, the first motor 602 rotates ninety degrees, after automatic suspension, the stirred carbon electrode materials are limited through the corresponding quantitative plates 605, the automatic downward rolling is prevented, the quantitative feeding effect is achieved, one carbon electrode material is conveyed at a time, the internal and external processing is convenient to perform better, then the controller 7 starts the multi-stage electric push rod 904, the U-shaped plate 901 is pulled to move downwards, the two connecting rods 902 and the two receiving rollers 903 are driven to move downwards, under the action of gravity, the carbon electrode materials move downwards along with the receiving rollers 903, when the U-shaped plate 901 moves to the lower part of the two external grinding rollers 202, the multi-stage electric push rod 904 is suspended, the carbon electrode materials are just embedded between the two external grinding rollers 202 and are contacted with the two external grinding rollers 202, one side of the two arc-shaped baffles 908 close to the top is respectively positioned at two ends of the carbon electrode materials close to the bottom, the two arc-shaped baffles 908 limit the carbon electrode materials, when the subsequent external processing is prevented, the position deviation of the carbon electrode material influences the subsequent internal processing, then the second motor 205 is controlled by the controller 7 to start, one gear 203 is driven to rotate through the output end of the second motor 205, meanwhile, the toothed belt 204 which is in meshed connection with the second motor is driven to rotate, the other gear 203 is driven to rotate under the rotation of the toothed belt 204, so that the two rotating rods 201 rotate in the same direction at the same time, the two external grinding rollers 202 are further driven to rotate, the carbon electrode material is subjected to the external grinding processing, in the actual use process, the distance between the two grinding rollers 202 is correspondingly matched according to the size of the carbon electrode material, the rotating speed of the stepping motor 911 is set according to the actual situation, the carbon electrode material falls between the two grinding rollers 202, after the external processing is finished, the multi-stage electric push rod 904 is started again, under the support of two multi-section telescopic rods 905 and two springs 906, the multi-stage electric push rod 904 is convenient to push the U-shaped plate 901 to move upwards steadily, the auxiliary support is added, the moving stability is increased, under the pushing of the multi-stage electric push rod 904, the polished carbon electrode material is pushed upwards to the original position through the cooperation of the U-shaped plate 901, the connecting rod 902 and the material receiving roller 903, then the controller 7 controls the two second hydraulic rods 303 to start simultaneously, the two protective baffles 305 are pushed to move in opposite directions, when the two protective baffles 305 move to the other side of the carbon electrode material, the two second hydraulic rods 303 automatically pause, the two protective baffles 305 are in a structure as shown in fig. 7, two sides are arranged in a plane, the middle part close to one side is provided with an arc-shaped outwards protruding part, at the moment, the plane part of the two protective baffles 305 close to one end is respectively moved to the other side of the carbon electrode material, under the cooperation of the two wear-resistant baffles 304, the two sides of the carbon electrode material are limited, under the action of the two arc-shaped baffles 908, the two ends of the carbon electrode material are limited (908 arc-shaped baffles are contacted with the outer surfaces of the carbon electrodes close to the edges, so that the carbon electrodes are limited, the conical screw drill 405 is positioned at the center of the two ends of the carbon electrodes, the drilling is not influenced), the two output ends of the two-shaft motor 401 and the two third motors 404 are controlled by the controller 7 to be started simultaneously, the two lead screws 402 are driven to rotate simultaneously by the two output ends of the two-shaft motor 401, the two L-shaped frames 403 are driven to move relatively in the opposite directions simultaneously under the limitation of the two rectangular slide holes 15, the two conical screw drill 405 is driven to move relatively to the two ends of the carbon electrode material, and under the driving of the output ends of the two third motors 404, the two taper thread drills 405 are driven to carry out internal drilling processing on two ends of the carbon electrode material so as to carry out internal electrode hole processing, after the internal drilling processing is finished, the output end of the double-shaft motor 401 reversely rotates to drive the two L-shaped frames 403 to move in opposite directions and drive the two third motors 404 and the two taper thread drills 405 to reset, during external processing, the controller 7 is used for simultaneously starting the industrial dust suction fan 502, the plurality of taper dust suction covers 509 face the direction of the moving assembly 9, the four taper dust suction covers 509 positioned on two sides of the two fixed pipes 508 face the two ends of the carbon electrode material respectively, dust generated during the internal and external processing is sucked into the fixed pipes 508 through the plurality of taper dust suction covers 509, then the air with the dust is pumped into the U-shaped pipes 507 and the dust suction pipes 506 in sequence, finally the air with the dust is discharged into the needled felt dust collection bag 503 through the output end of the industrial dust suction fan 502, the filtering efficiency of the needled felt dust bag 503 can reach more than 99.9%, particulate matters and dust in the air can be effectively filtered, the filtering speed is high, the filter speed is high, the needled felt dust bag 503 can be efficiently filtered, in addition, the needled felt dust bag 503 has good wear resistance and tensile strength, can keep stable filtering effect under the action of high air flow, finally, clean air is discharged, thereby achieving the dust removing effect, reducing the pollution of dust to the working environment, after the internal and external processing of the carbon electrode material is finished, the controller 7 controls the servo motor 801 and the stepping motor 911 to start, the output end of the servo motor 801 drives the rotating shaft 802 to rotate, then drives the cleaning roller 803 to rotate, further drives the anti-static dust removing brush 804 to rotate, the anti-static dust removing brush 804 contacts with the outer surface of the carbon electrode material, the outer surface of the carbon electrode material is cleaned by the anti-static dust removing brush 804, meanwhile, the output end of the stepping motor 911 drives one leather wheel 909 to rotate, then drives the belt 910 to rotate, so that the other leather wheel 909 rotates, further drives the two connecting rods 902 to rotate in the same direction, and drives the two material receiving rollers 903 to rotate, so that the carbon electrode material rotates on the outer surfaces of the two material receiving rollers 903, the rotating speed of the servo motor 801 is slower than that of the stepping motor 911, the surfaces of the carbon electrode material are cleaned through the anti-static ash cleaning brushes 804, the dust which is cleaned off is pumped out by the dust collection assembly 5, the effect of surface ash removal is achieved, the problem that more dust covers the outer surfaces of the graphite plates after the carbon electrode is processed inside and outside by the existing carbon electrode processing center is solved, if the dust is not cleaned timely, oxygen in the air is easy to be absorbed by the dust, the surfaces of the carbon electrode are oxidized, the performance and service life of the carbon electrode are affected is solved, after the carbon electrode material completes inside and outside processing and outside surface ash removal, the two first hydraulic rods 302 are started again, the two wear-resistant baffles 304 are pulled to reset, one sides of the carbon electrode material lose limit, the two second hydraulic rods 303 continue to drive the two protection baffles 305 to move relatively, the two protection baffles 305 are enabled to move relatively, and the two protection baffles 305 protrude from the upper side of the carbon electrode material to contact the upper arc-shaped material 10, and the upper electrode material is convenient to roll down, and the material is contacted with the upper arc-shaped material, and the upper electrode material is convenient to roll.

The second motor 205, the first hydraulic rod 302, the second hydraulic rod 303, the dual-shaft motor 401, the third motor 404, the industrial dust collection fan 502, the first motor 602, the controller 7, the servo motor 801, the multi-stage electric push rod 904 and the stepper motor 911 are all in the prior art, and the components and the use principle thereof are all in the public technology, and are not explained herein too much.

Although the present invention has been described with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described, or equivalents may be substituted for elements thereof, and any modifications, equivalents, improvements and changes may be made without departing from the spirit and principles of the present invention.

Claims (4)

1. Inside and outside integrative machining center of carbon electrode, its characterized in that includes: the dust collection device comprises a machine tool (1), an external machining assembly (2), an internal machining assembly (4), a moving assembly (9) and a cleaning assembly (8), wherein the dust collection assembly (5) is fixedly arranged on the outer surface of one side of the machine tool (1), and a controller (7) is arranged on the front surface, close to the other side, of the machine tool (1);

the cleaning assembly (8) comprises a servo motor (801), a rotating shaft (802) is fixedly arranged at the output end of the servo motor (801), a cleaning roller (803) is fixedly arranged at the center of the outer surface of the rotating shaft (802), an anti-static ash cleaning brush (804) is fixedly arranged on the outer surface of the cleaning roller (803), reinforcing plates (805) are movably sleeved on the outer surfaces of the rotating shaft (802) close to the two ends, the tops of the two reinforcing plates (805) are fixedly arranged at the top of the interior of the machine tool (1), and the outer surface of the servo motor (801) is fixedly arranged on the rear surface of one reinforcing plate (805) close to the bottom through a connecting plate;

the dust collection assembly (5) comprises a support plate (501), an industrial dust collection fan (502) is fixedly arranged at the top of the support plate (501), a dust collection pipe (506) is connected to the input end of the industrial dust collection fan (502) through a flange plate, a needled felt dust collection bag (503) is arranged at the output end of the industrial dust collection fan (502), a U-shaped pipe (507) is fixedly connected to one end of the dust collection pipe (506), fixing pipes (508) are fixedly arranged at two ends of the U-shaped pipe (507), a plurality of conical dust collection covers (509) are fixedly communicated with the outer surfaces of the fixing pipes (508), the outer surfaces of the support plate (501) are fixedly arranged on the outer surfaces of one side, close to the top, of a machine tool (1) through reinforcing ribs, of the support plate (501) is fixedly provided with a first partition plate (504), and a second partition plate (505) is fixedly arranged at the top, close to the front surface, of the support plate (501).

The external machining assembly (2) comprises two rotating rods (201), external grinding rollers (202) are fixedly arranged on the outer surfaces of the two rotating rods (201), gears (203) are fixedly arranged at one ends of the two rotating rods (201), toothed belts (204) are connected to the outer surfaces of the two gears (203) in a meshed mode, a digital mounting plate (206) is arranged on the front surface, close to the bottom, of the machine tool (1) through bolts, a second motor (205) is fixedly arranged in the digital mounting plate (206), the output end of the second motor (205) is fixedly connected with the front surface of one of the gears (203), one ends of the two rotating rods (201) movably penetrate through the front surface of the machine tool (1), and the other ends of the two rotating rods (201) are movably embedded in the rear surface, close to the bottom, of the machine tool (1);

the internal machining assembly (4) comprises a double-shaft motor (401), two output ends of the double-shaft motor (401) are fixedly provided with screw rods (402), the outer surfaces of the two screw rods (402) close to one end are respectively sheathed with L-shaped frames (403) in a threaded manner, the bottoms of the interiors of the two L-shaped frames (403) are respectively fixedly provided with a third motor (404), the output ends of the two third motors (404) are respectively provided with a conical threaded drill bit (405), the front surface and the rear surface of the machine tool (1) are respectively provided with a rectangular slide hole (15), the outer surfaces of the two L-shaped frames (403) close to the bottoms are respectively movably sheathed in the interiors of the two rectangular slide holes (15), the outer surfaces of the two L-shaped frames (403) are respectively provided with a supporting slide hole (408), the interiors of the two supporting slide holes (408) are respectively movably sheathed with a supporting rod (406), one end of each supporting rod (406) is respectively fixedly arranged on the front surface and the rear surface of the machine tool (1) close to the top, the two outer surfaces (402) are respectively fixedly sheathed with a plurality of supporting blocks (506) at the bottom of the inner surfaces (407) of the machine tool (1) and the inner surfaces (407) of the machine tool (1), two ends of the two fixing pipes (508) are respectively fixed on a front surface wall and a rear surface wall of the machine tool (1) close to two sides;

the movable assembly (9) comprises a U-shaped plate (901), two connecting rods (902) are movably embedded in the U-shaped plate (901), two material receiving rollers (903) are fixedly installed on the outer surfaces of the connecting rods (902), leather wheels (909) are fixedly installed at one ends of the connecting rods (902), belts (910) are movably sleeved on the outer surfaces of the leather wheels (909), a stepping motor (911) is fixedly installed on the front surface of the U-shaped plate (901) through an auxiliary plate, the output end of the stepping motor (911) is fixedly connected with the front surface of one of the leather wheels (909), a multistage electric push rod (904) is fixedly installed at the center of the bottom of the U-shaped plate (901), arc-shaped baffles (908) are fixedly installed on the tops of the U-shaped plate (901) close to the front surface and the rear surface, two ends of the connecting rods (902) respectively movably penetrate through the front surface and the rear surface of the U-shaped plate (901), a bottom end of the multistage electric push rod (904) is fixedly installed at the center of the inner bottom of the machine tool (1), a plurality of telescopic rods (905) are fixedly installed on the front surface of the U-shaped plate (901), a telescopic rod (905) is fixedly installed on the front surface of the U-shaped plate (901), a telescopic rod (905), the bottoms of the two multi-section telescopic rods (905) and one ends of the two springs (906) are respectively and fixedly arranged at the bottoms, close to the front surface wall and the rear surface wall, of the machine tool (1).

2. The carbon electrode inner and outer integrated machining center according to claim 1, wherein: the machine tool comprises a machine tool body (1), and is characterized in that a protection component (3) is arranged on the machine tool body (1), a quantitative feeding component (6) is arranged on the machine tool body (1), the protection component (3) comprises four L-shaped plates (301), wherein two first hydraulic rods (302) are fixedly arranged on the inner walls of the L-shaped plates (301), two second hydraulic rods (303) are fixedly arranged on the inner walls of the L-shaped plates (301), fixed blocks (306) are fixedly arranged at one ends of the first hydraulic rods (302), fixed blocks (306) are fixedly arranged at one ends of the two second hydraulic rods (303), wear-resisting baffle plates (304) are fixedly arranged on the outer surfaces of the fixed blocks (306) fixedly connected with the first hydraulic rods (302), and protection baffle plates (305) are fixedly arranged on the outer surfaces of the fixed blocks (306) fixedly connected with the second hydraulic rods (303).

3. The carbon electrode inner and outer integrated machining center according to claim 2, wherein: four the average division of L template (301) is two sets of, and two sets of the surface of L template (301) is fixed mounting respectively at the front surface and the back surface of lathe (1), first slide hole (16) have all been seted up to the front surface and the back surface of lathe (1), second slide hole (14) have all been seted up to the front surface and the back surface of lathe (1), two the surface of wear-resisting baffle (304) is movable the embedding respectively and is established in the inside of two first slide holes (16), two the surface of protection baffle (305) is movable the embedding respectively and is established in the inside of two second slide holes (14), ration material loading subassembly (6) are including two fixed plates (601), one of them the surface of fixed plate (601) is through auxiliary block fixed mounting first motor (602).

4. A carbon electrode inner and outer integrated machining center according to claim 3, wherein: the fixed shaft (603) is fixedly arranged at the output end of the first motor (602), a fixed cylinder (604) is fixedly arranged at the center of the outer surface of the fixed shaft (603), a plurality of metering plates (605) are arranged on the outer surface of the fixed cylinder (604) at equal intervals, a blanking opening (12) is formed in the outer surface of one side of the machine tool (1), an inclined blanking plate (10) is fixedly arranged at the bottom of the blanking opening (12), a feeding opening (13) is formed in the outer surface of the other side of the machine tool (1), an inclined feeding plate (11) is fixedly arranged at the bottom of the feeding opening (13), and two fixed plates (601) are fixedly arranged on the front surface and the rear surface of the inclined feeding plate (11) on one side, which is close to the bottom, of the opposite sides.