Quartz sand ceramic low-power-consumption asynchronous ball-milling equipment for optimizing material processing
Technical Field
The invention relates to the field of ceramic processing, in particular to quartz sand ceramic low-power-consumption asynchronous ball milling equipment for optimizing material processing.
Background
The ball mill is suitable for grinding various ores and other materials and is widely used in the industries of mineral separation, building materials, chemical industry and the like; for example, in the process of processing quartz sand ceramics by a ball mill, raw materials are fed into equipment, then the ceramics are polished by balls, and finally the polished materials are discharged.
The material of prior art is because the raw materials surface is comparatively crude after getting into a section of thick bamboo, and the material often appears in transportation process and will import the inner wall friction or can not smoothly send into the phenomenon that leads to the material to pile up at the feed inlet because of the friction, also can overlap when the volume after the material is polished differs in size and lead to the material ejection of compact and pile up at the discharge gate when the ejection of compact, influence the processing progress.
Disclosure of Invention
The invention mainly aims to overcome the defects of the prior art, and provides quartz sand ceramic low-power-consumption asynchronous ball milling equipment for optimizing material processing, which aims to solve the problems that after materials enter a cylinder, because the surfaces of raw materials are rough, the materials rub the inner wall of an inlet in the conveying process or the materials are stacked at a feed inlet due to the fact that the materials cannot be smoothly conveyed due to friction, and the materials are stacked at a discharge outlet due to different sizes of the polished materials in the discharging process, so that the processing progress is influenced.
The invention is realized by adopting the following technical scheme: the utility model provides an optimize asynchronous ball-milling equipment of quartz sand pottery low-power consumption of material processing, its structure includes motor, ball mill frame, ball-milling pan feeding mouth, ball-milling section of thick bamboo, ball-milling discharge gate, even board, the motor is installed at ball mill frame left end, ball mill frame and the locking of ball-milling bobbin base portion, both ends and ball-milling pan feeding mouth, ball-milling discharge gate erection joint about the ball-milling section of thick bamboo, even board is installed to ball-milling section of thick bamboo right-hand member, ball-milling pan feeding mouth is crossed a section of thick bamboo by feed inlet, feeding and is constituteed, the left end welding is crossed a section of thick bamboo to feed inlet and feeding, the ball-milling discharge gate comprises crossbearer leg, linking section of thick bamboo, branch feed cylinder, play feed cylinder, both ends erection joint about crossbearer leg, branch feed.
Further preferably, the feed inlet comprises a necking and a necking connection ring, and the necking outer ring is buckled with the necking connection ring.
Preferably, the feeding transition cylinder comprises an outer cylinder, an inner cylinder and a connecting feeding disc, and the left end and the right end of the inner cylinder are embedded with the outer cylinder and the connecting feeding disc.
Preferably, the connecting feeding disc comprises a fan-dividing disc, a middle fixed disc and a feeding reducing port, the center of the fan-dividing disc is locked with the middle fixed disc, and the middle of the middle fixed disc is provided with the feeding reducing port.
Preferably, the inner ring side of the material separating cylinder is provided with a thread wall, the inner ring side of the material discharging cylinder is provided with a material stepped device, and the material separating cylinder and the material discharging cylinder form a vertical structure.
Further preferably, the thread wall comprises a thread gap and a thread rail groove, and the thread gap is connected with the left side and the right side of the thread rail groove in an embedded mode.
Preferably, the material stepping device comprises a conveying transverse plate, a conveying transverse groove, a conveying transverse frame and a conveying concave plate, the conveying transverse plate and the conveying concave plate are connected with the upper end rail of the conveying transverse frame, and the conveying transverse groove is formed in the front side and the rear side of the conveying transverse frame.
Further preferably, the even plate comprises a butt joint even plate and an even controller, the front side of the butt joint even plate is connected with the even controller in an embedded mode, the even controller is provided with a spring plate and a pushing circle, and the right end of the spring plate is welded with the pushing circle.
Advantageous effects
After the motor of the invention is operated, raw materials enter from a ball milling inlet and then are subjected to ball milling operation in a ball milling barrel, then the materials are sent out from a ball milling outlet, after the materials enter the ball milling inlet, the materials are firstly subjected to necking (a material port comprising necking is designed in the middle to realize that the materials can be centrally sent into the ball milling barrel) and then enter an inner barrel to be polished, a fan-shaped disc and a middle fixed disc are matched for transmission in the polishing process to realize that a feeding reducer moves left and right under the movement of the middle fixed disc, the diameter of the feeding reducer expands and reduces along with the middle fixed disc during the movement, the polished materials are more smoothly sent from the feeding reducer, then the materials enter the ball milling barrel, the materials are sent into the ball milling barrel according to a proper proportion, the ball milling barrel rotates to generate centrifugal force, then steel balls in the ball milling barrel are driven to a certain height to fall down to generate heavy impact and grinding on the materials, (meanwhile, even accuse ware can be adjusted according to ball mill section of thick bamboo pivoted frequency and smoothness degree, push away the circle and carry out reciprocating motion under the effect of spring plate and make ball mill section of thick bamboo can not produce the phenomenon that surpasss slew velocity because of the striking of inside material and steel ball and take place), the material is sent to the ball-milling discharge gate from ball mill section of thick bamboo after accomplishing the grinding, through the mode of screw thread rail groove with auger delivery, move the material and arrange on the rank glassware, carry to the equipment outside again, when rank glassware moves, the material covers on the screw thread rail groove, screw thread rail groove carries out one step of laminating with carrying the concave plate under the action of gravity, the orderly, stable transport of material has been guaranteed, carry the horizontal groove and carry the horizontal shelf cooperation slip realization material to see off after that.
Compared with the prior art, the invention has the beneficial effects that: raw materials from throat department in advance in the strip section of thick bamboo with the edges and corners polish and get into the ball mill section of thick bamboo from linking up feed tray again, roughly polish the raw materials in advance, inner wall takes place scratch or the accumulational phenomenon of material because of the material is coarse when having reduced the material import and carrying, the material is polished and is accomplished the back and is seen off from the ball mill discharge gate department, the spiral distribution through the branch feed cylinder realizes sending out in order through going out the feed cylinder again in proper order, even the volume of material is not of uniform size can not take place the material yet and pile up the condition of jam and appear, machining efficiency obtains effectively improving.
Drawings
Other features, objects and advantages of the invention will become more apparent upon reading of the detailed description of non-limiting embodiments with reference to the following drawings:
FIG. 1 shows a schematic structural diagram of a quartz sand ceramic low-power consumption asynchronous ball milling device for optimizing material processing.
Fig. 2 shows a schematic structure of a ball mill feeding port of the present invention.
Fig. 3 shows a schematic structural diagram of a ball mill feed inlet according to the present invention.
Fig. 4 shows a schematic view of the structure of the splice feed tray of the present invention.
Fig. 5 shows a schematic structural view of a ball mill discharge port of the present invention.
Fig. 6 shows a structural schematic diagram of the material separating barrel and the material discharging barrel of the invention.
Fig. 7 shows a schematic view of the construction of the threaded wall of the invention.
Fig. 8 shows a schematic view of the structure of the stage of the present invention.
FIG. 9 shows a schematic of the construction of a shim plate according to the present invention.
In the figure: the ball mill comprises a motor 1, a ball mill frame 2, a ball mill feeding port 3, a ball mill barrel 4, a ball mill discharging port 5, a uniform plate 6, a feeding port 30, a feeding transition barrel 31, a cross frame welding foot 50, a joining barrel 51, a material separating barrel 52, a material discharging barrel 53, a reducing port 300, a reducing port joining ring 301, an outer barrel 310, an inner barrel 311, a joining feeding disk 312, a fan-dividing disk 3120, a middle fixing disk 3121, a feeding reducing port 3122, a threaded wall 520, a material stepping device 521, a thread gap 5200, a threaded rail groove 5210, a conveying transverse plate 5210, a conveying transverse groove 5211, a conveying cross frame 5212, a conveying concave plate 5213, a butt joint uniform plate 60, a uniform controller 61, a spring plate 610 and a pushing circle 611.
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.
Referring to fig. 1-9, the invention provides a technical scheme of quartz sand ceramic low-power consumption asynchronous ball milling equipment for optimizing material processing, which comprises the following steps: the structure of the ball mill comprises a motor 1, a ball mill frame 2, a ball mill inlet 3, a ball mill barrel 4, a ball mill outlet 5 and a homogenizing plate 6, wherein the motor 1 is arranged on the ball mill frame 2, the ball mill frame 2 is locked with the ball mill barrel 4, the ball mill barrel 4 is connected with the ball mill inlet 3 and the ball mill outlet 5 in an installing way, the homogenizing plate 6 is arranged on the ball mill barrel 4, the ball mill inlet 3 comprises a feed inlet 30 and a feed transition barrel 31, the penetration of the feed inlet 30 is designed in the middle, so that initially fed materials can be fed into the ball mill barrel 4 in the middle, the feed inlet 30 is welded with the feed transition barrel 31, the ball mill outlet 5 comprises a cross frame welding foot 50, a connecting barrel 51, a material separating barrel 52 and a material discharging barrel 53, the cross frame welding foot 50 realizes the auxiliary fixation of the ball mill barrel 4, the stability of the operation of the device is improved, the cross frame welding foot 50 and the material separating barrel 52 are connected with, the material dividing cylinder 52 is connected with the material discharging cylinder 53 through a shaft, the feeding port 30 comprises a reducing port 300 and a reducing connecting ring 301, the reducing port 300 is buckled with the reducing connecting ring 301, the feeding transition cylinder 31 comprises an outer cylinder 310, an inner cylinder 311 and a connecting feeding disc 312, the inner cylinder 311 is embedded with the outer cylinder 310 and the connecting feeding disc 312, the connecting feeding disc 312 comprises a dividing fan disc 3120, a middle fixed disc 3121 and a feeding reducing port 3122, the diameter of the feeding reducing port 3122 can be changed, so that when materials with different sizes pass through the feeding reducing port 3122, the penetrating port can be flexibly enlarged or reduced, the materials can be smoothly conveyed, the dividing fan disc 3120 is locked with the middle fixed disc 3121, the middle fixed disc 3121 is provided with the feeding reducing cylinder port 3122, the material dividing cylinder 52 is provided with a threaded wall 520, the material discharging cylinder 53 is provided with a material feeder 521, the material dividing cylinder 52 and the material discharging cylinder 53 form a vertical structure, the thread wall 520 comprises a thread gap 5200 and a thread rail groove 5210, the thread gap 5200 is embedded and connected with the thread rail groove 5210, the thread rail groove 5210 moves and arranges materials on the material displacement device 521 in a spiral conveying manner, and then conveys the materials to the outside of the equipment, the material displacement device 521 is orderly conveyed, the material displacement device comprises a conveying transverse plate 5210, a conveying transverse groove 5211, a conveying transverse frame 5212 and a conveying concave plate 5213, the conveying transverse plate 5210 and the conveying concave plate 5213 are connected with the conveying transverse frame 5212 in a rail way, the conveying transverse groove 5211 is arranged on the conveying transverse frame 5212, the material displacement plate 6 comprises a butt-joint uniform plate 60 and a uniform control device 61, the butt-joint uniform plate 60 is embedded and connected with the uniform control device 61, the uniform control device 61 is provided with a spring plate 610 and a pushing circle 611, the spring plate 610 is welded with the pushing circle 611, when the material displacement device 521 runs, the material covers the thread rail groove 5210 and the conveying concave plate 5213 are attached in one step under the action of gravity, the ordered and stable conveying of the materials is ensured, the transverse conveying grooves 5211 and the transverse conveying frames 5212 are matched and slide to realize the conveying of the materials, and the transmission is flexible.
After the motor 1 operates, raw materials enter from a ball milling feeding port 3 and then are subjected to ball milling operation in a ball milling barrel 4, then the materials are sent out from a ball milling discharging port 5, after the materials enter into the ball milling feeding port 3, the materials firstly enter into an inner barrel 311 to be ground through a throat 300 (the materials can be sent into the ball milling barrel 4 in a centered mode through a material port comprising the throat 300), a fan disc 3120 and a middle fixed disc 3121 are in matched transmission in the grinding process, the feeding reducing port 3122 moves left and right along with the movement of the middle fixed disc 3121, the diameter of the feeding reducing port 3122 expands and reduces along with the middle fixed disc 3121 during movement, the ground materials are conveniently and smoothly sent from the feeding reducing port 3122, then the materials enter into the ball milling barrel 4, the materials are sent into the ball milling barrel 4 according to a proper proportion, the ball milling barrel 4 rotates to generate centrifugal force and then brings the inner steel balls to a certain height and then fall down, the materials are hit and ground (meanwhile, the uniform controller 61 can adjust according to the rotating frequency and fluency of the ball grinding cylinder 4, the pushing circle 611 moves back and forth under the action of the spring plate 610, so that the ball grinding cylinder 4 cannot exceed the rotating speed caused by the impact of the internal materials and the steel balls), the materials after being ground are sent to the ball grinding discharge port 5 from the ball grinding cylinder 4, the materials are moved and arranged on the material grading device 521 in a spiral conveying mode through the threaded rail groove 5210 and then are conveyed to the outside of the equipment, when the material grading device 521 operates, the materials cover the threaded rail groove 5210, the threaded rail groove 5210 is attached to the conveying concave plate 5213 in one step under the action of gravity, the ordered and stable conveying of the materials is ensured, and then the conveying transverse groove 5211 is matched with the conveying transverse frame 5212 to slide so as to send out the materials.
Compared with the prior art, the invention has the technical progress that: the raw materials from throat 300 department in advance in the strip section of thick bamboo 311 with the edges and corners polish and get into ball mill section of thick bamboo 4 from linking feeding dish 312 again, roughly polish the raw materials in advance, inner wall takes place the scratch or the accumulational phenomenon of material because of the material is coarse when having reduced the material import and carrying, the material is polished and is seen off from ball mill discharge gate 5 after accomplishing, the spiral distribution through charging barrel 52 realizes sending out in order through charging barrel 53 again in proper order, even the volume of material is not of uniform size can not take place the material yet and pile up the condition appearance of jam, machining efficiency obtains effectively improving.
Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that various changes in the embodiments and/or modifications of the invention can be made, and equivalents and modifications of some features of the invention can be made without departing from the spirit and scope of the invention.