CN113418390B - Smelting device for producing and processing nano ceramic dry particles - Google Patents

Abstract

The invention discloses a smelting device for producing and processing dry nano ceramic particles, which belongs to the technical field of ceramic processing and comprises a mounting plate, a conveying belt, a weighing mechanism, an abrasive mechanism, a stirring mechanism, a turnover mechanism, a smelting box and a particle manufacturing machine. The nano ceramic dry particle smelting processing is automatically completed through the weighing mechanism, the grinding mechanism, the stirring mechanism, the turnover mechanism, the smelting box and the particle manufacturing machine.

Description

Smelting device for producing and processing nano ceramic dry particles

Technical Field

The invention belongs to the technical field of ceramic processing, and particularly relates to a smelting device for producing and processing dry nano ceramic particles.

Background

The nano ceramic is a composite material manufactured by introducing nano ceramic particles, whiskers, fibers and the like into a ceramic matrix to improve the performance of the ceramic, is beneficial to improving the mechanical property of the matrix material at room temperature and improving the high-temperature performance, can be cut and processed, and has superplasticity. Therefore, the production of the ceramic nanometer dry particles is an important process for improving the ceramic matrix.

Application number 2020226423376 discloses a device is smelted in production and processing of dry grain of pottery, including base, smelting case, heat conduction pole, electric heating board, outlet duct, spout etc. although can produce ceramic granule, but the proportion and the weight of raw and other materials can not accurate control, can not go out fast to mix stirring and extrude as much. Aiming at the problems, the invention provides a smelting device for producing and processing dry nano ceramic particles.

Disclosure of Invention

Aiming at the technical problems, the technical scheme adopted by the invention is as follows: a smelting device for producing and processing dry nano ceramic particles comprises a mounting plate, a conveying belt, a weighing mechanism, a grinding mechanism, a stirring mechanism, a turnover mechanism, a smelting box and a particle making machine; the conveyer belt fixed mounting on the mounting panel.

The weighing mechanism is fixedly arranged on the mounting plate and comprises a weighing box and a gravity sensor, and the gravity sensor is fixedly arranged on a lower end cover of the weighing box.

Abrasive mechanism fixed mounting on the mounting panel, abrasive mechanism include conveyer belt and abrasive roller, the abrasive roller set up the one end that is close to abrasive mechanism at the conveyer belt for with the raw materials grinding.

Rabbling mechanism fixed mounting on the mounting panel, the rabbling mechanism include agitator, extrusion disc, stirring board, the stirring board be arranged in the raw materials of stirring agitator, the extrusion disc be arranged in the raw materials after the extrusion stirring.

The turnover mechanism is fixedly arranged on the mounting plate and is connected with the stirring mechanism, and the turnover mechanism comprises a reversing assembly for converting the positions of the extrusion disc and the stirring plate.

The smelting box is fixedly arranged on the mounting plate and used for smelting raw materials.

The particle making machine is fixedly arranged on the mounting plate and comprises a particle forming roller for making dry ceramic particles.

Further, weighing machine construct still include the hopper, hopper fixed mounting on the mounting panel, the hopper on fixed mounting have propelling movement electric cylinder and weighing box, propelling movement electric cylinder stretch out end fixed mounting have a push plate, push plate slidable mounting inside the hopper, rack slidable mounting is on weighing box, rack and the meshing cooperation of the gear that opens and shuts, open and shut gear fixed mounting epaxial at the lower end cover.

Further, abrasive mechanism still include the motor, motor fixed mounting on the mounting panel, motor output shaft be connected with the drive belt, the drive belt set up on the conveyer belt for drive abrasive roller rotates, pressfitting cam fixed mounting is on the jackshaft of abrasive roller, pressfitting cam and pressfitting board sliding fit, pressfitting board and conveyer belt in the middle of install reset spring.

Further, rabbling mechanism still including the installation disc, the installation disc pass through the stand and be connected with the extrusion disc, the agitator on be provided with conical gear group, conical gear group pass through the band pulley drive on the conveyer belt, the installation disc on be provided with cylindrical gear group, the stirring board install on cylindrical gear group, stirring board and conical gear group meshing cooperation, the stand be connected with tilting mechanism.

Further, tilting mechanism still include upset motor and drive gear group, upset motor output shaft on be connected with the upset drive belt, upset drive belt and drive gear group link, drive gear group set up on the riser, drive gear group output and driven conical gear meshing, driven conical gear rotate and install on the lead screw, rotate the one end of installing the lead screw on the mounting bracket, the lead screw other end rotate the installation with the installation disc, mounting bracket fixed mounting on the mounting panel, driven conical gear and lead screw meshing cooperation, lead screw upper end be provided with the inclined plane.

Furthermore, the driving gear set comprises an incomplete gear, the incomplete gear is fixedly installed with an overturning transmission belt, the incomplete gear is rotatably installed on a vertical plate, the incomplete gear is meshed with a lower cylindrical gear, the lower cylindrical gear is rotatably installed on the vertical plate, an overturning cam is fixedly installed on the lower cylindrical gear, the overturning cam is in sliding fit with an arc-shaped plate on a transmission cylindrical gear, a shaft on which the transmission cylindrical gear is located is slidably installed on the vertical plate, a driving conical gear is fixedly installed on the shaft on which the transmission cylindrical gear is located, the driving conical gear is in meshing fit with a driven conical gear, a middle cylindrical gear and an upper cylindrical gear are rotatably installed on the vertical plate, when the transmission cylindrical gear is located at the upper part of the vertical plate, the transmission cylindrical gear is meshed with the upper cylindrical gear, when the transmission cylindrical gear is positioned at the lower part of the vertical plate, the transmission cylindrical gear is meshed with the middle cylindrical gear, and the middle cylindrical gear and the upper cylindrical gear are transmitted through the overturning transmission belt.

Further, tilting mechanism still include the screw thread and detain, the screw thread detain and rotate and install on the right angle pole, right angle pole fixed mounting on the mounting panel, the screw thread detain in the middle of set up hollow cylinder, hollow cylinder in the middle of be provided with the inclined plane, the screw thread detain the upper portion and be connected with torsion spring, torsion spring upper end and right angle pole fixed connection.

Furthermore, the inclined plane on the lead screw and the inclined plane in the hollow cylinder form sliding fit.

Furthermore, the smelting box also comprises a sliding plate for pushing out the smelted raw materials.

Compared with the prior art, the invention has the beneficial effects that: (1) the nano ceramic dry particle smelting machine automatically finishes the smelting processing of nano ceramic dry particles through the weighing mechanism, the grinding mechanism, the stirring mechanism, the turnover mechanism, the smelting box and the particle manufacturing machine, and has high automation degree and simple operation; (2) the weighing mechanism is provided with the gravity sensor, so that the weight of the added raw materials can be detected on line in real time, the precision is high, and the real-time adjustment is convenient; (3) can be according to actual processing progress through tilting mechanism, two processes are stirred and are extruded in quick adjustment, promote stirring speed and shaping speed.

Drawings

Fig. 1 and 2 are schematic views of the overall structure of the present invention.

Fig. 3 is a partial structure schematic diagram of the weighing mechanism.

Fig. 4 is a partially enlarged schematic view of fig. 3.

Fig. 5 and 6 are schematic structural diagrams of a part of the abrasive mechanism of the invention.

Fig. 7 is a schematic structural view of the stirring mechanism.

Fig. 8 is a partially enlarged schematic view of fig. 7.

Fig. 9 is a schematic view of the turnover mechanism.

Fig. 10 is a partial structural schematic diagram of the turnover mechanism.

Detailed Description

The present invention will be further described with reference to specific examples, which are illustrative of the invention and are not to be construed as limiting the invention.

Wherein the showings are for the purpose of illustration only and are shown by way of illustration only and not in actual form, and are not to be construed as limiting the present patent; to better explain the embodiments of the present invention, some components in the drawings may be omitted, enlarged or reduced, and do not represent the size of an actual product, and it may be understood that some well-known structures in the drawings and descriptions thereof may be omitted to those skilled in the art.

Example (b): the smelting device for producing and processing the dry nano-ceramic particles as shown in fig. 1-10 comprises a mounting plate 1, a conveying belt 4, a weighing mechanism 2, an abrasive mechanism 3, a stirring mechanism 5, a turnover mechanism 6, a smelting box 7 and a particle making machine 8; the conveyer belt 4 is fixedly arranged on the mounting plate 1, the weighing mechanism 2 comprises a weighing box 204 and a gravity sensor 205, the gravity sensor 205 is fixedly arranged on a lower end cover of the weighing box 204, the grinding material mechanism 3 is fixedly arranged on the mounting plate 1, the grinding material mechanism 3 comprises a conveyer belt 303 and a grinding material roller 304, the grinding material roller 304 is arranged at one end of the conveyer belt 303 close to the grinding material mechanism 3 and is used for grinding raw materials, the stirring mechanism 5 is fixedly arranged on the mounting plate 1, the stirring mechanism 5 comprises a stirring barrel 501, an extrusion disc 503 and a stirring plate 505, the stirring plate 505 is used for stirring the raw materials in the stirring barrel 501, the extrusion disc 503 is used for extruding the stirred raw materials, the turnover mechanism 6 is fixedly arranged on the mounting plate 1, the turnover mechanism 6 is connected with the stirring mechanism 5, the turnover mechanism 6 comprises a reversing component and is used for converting the positions of the extrusion disc 503 and the stirring plate 505, the smelting box 7 is fixedly arranged on the mounting plate 1 and used for smelting raw materials.

The weighing mechanism 2 further comprises a hopper 201, the hopper 201 is fixedly installed on the installation plate 1, a pushing electric cylinder 202 and a weighing box 204 are fixedly installed on the hopper 201, a pushing plate 203 is fixedly installed at the extending end of the pushing electric cylinder 202, the pushing plate 203 is slidably installed inside the hopper 201, a rack 206 is slidably installed on the weighing box 204, the rack 206 is meshed with the opening and closing gear 207, and the opening and closing gear 207 is fixedly installed on a shaft of the lower end cover. During operation, pour the raw materials into hopper 201, then start propelling movement electric cylinder 202, promote propelling movement board 203 forward and make the raw materials enter into weighing box 204, the gravity inductor 205 of weighing box 204 lower extreme carries out weight detection, after the weight satisfies the demands, utilize the cylinder to promote rack 206 forward, drive gear 207 that opens and shuts and rotate for the lower end cover of weighing box 204 is opened, and the raw materials is transferred into on the conveyer belt 303.

The abrasive mechanism 3 further comprises a motor 301, the motor 301 is fixedly mounted on the mounting plate 1, an output shaft of the motor 301 is connected with a transmission belt 302, the transmission belt 302 is arranged on a transmission belt 303 and used for driving the abrasive roller 304 to rotate, a pressing cam 306 is fixedly mounted on an intermediate shaft of the abrasive roller 304, the pressing cam 306 is in sliding fit with a pressing plate 305, and a return spring 307 is mounted between the pressing plate 305 and the transmission belt 303. Starter motor 301, drive belt 302 and rotate, so that conveyer belt 303 rotates and carry the raw materials forward, simultaneously abrasive roller 304 rotates, grind the raw materials, pressfitting cam 306 rotates along with abrasive roller 304, shake from top to bottom through driving pressfitting board 305 constantly, impress the raw materials in abrasive roller 304, convenient quick abundant grinding, reset spring 307 plays the effect that resets, conveyer belt 4 drives through drive belt 302 on the abrasive mechanism 3 and rotates, the raw materials after the grinding passes through conveyer belt 4 and enters into agitator 501.

The stirring mechanism 5 further comprises a mounting disc 502, the mounting disc 502 is connected with the extrusion disc 503 through a stand column 504, a conical gear set 507 is arranged on the stirring barrel 501, the conical gear set 507 is driven by a belt wheel on the conveying belt 4, a cylindrical gear set 506 is arranged on the mounting disc 502, a stirring plate 505 is arranged on the cylindrical gear set 506, the stirring plate 505 is meshed with the conical gear set 507, and the stand column 504 is connected with the turnover mechanism 6. Conveyer belt 4 is when rotating along with drive belt 302, drives bevel gear set 507 equally and rotates, and agitator 501 side is provided with the feed inlet, can add other raw and other materials this moment, and bevel gear set 507 makes cylindrical gear set 506 rotate through gear drive, and fixed mounting rotates at stirring board 505 on cylindrical gear set 506, carries out abundant stirring to the material in agitator 501, starts tilting mechanism 6 after the stirring finishes.

Tilting mechanism 6 still includes upset motor 601 and drive gear group, be connected with upset drive belt 602 on the upset motor 601 output shaft, upset drive belt 602 and drive gear group link, drive gear group sets up on the riser, drive gear group output and driven conical gear 610 mesh, driven conical gear 610 rotates and installs on lead screw 611, the one end of installing lead screw 611 rotates on the mounting bracket 612, the lead screw 611 other end rotates the installation with installation disc 502, mounting bracket 612 fixed mounting is on mounting panel 1, driven conical gear 610 and lead screw 611 mesh cooperation, the lead screw 611 upper end is provided with the inclined plane. The turnover motor 601 is started to drive the turnover transmission belt 602 to rotate.

The driving gear set comprises an incomplete gear 603, the incomplete gear 603 is fixedly installed with an overturning transmission belt 602, the incomplete gear 603 is rotatably installed on a vertical plate, the incomplete gear 603 is meshed with a lower cylindrical gear 604, the lower cylindrical gear 604 is rotatably installed on the vertical plate, an overturning cam 605 is fixedly installed on the lower cylindrical gear 604, the overturning cam 605 is in sliding fit with an arc-shaped plate on a transmission cylindrical gear 606, a shaft on which the transmission cylindrical gear 606 is located is slidably installed on the vertical plate, a driving conical gear 609 is fixedly installed on the shaft on which the transmission cylindrical gear 606 is located, the driving conical gear 609 is in meshing fit with a driven conical gear 610, a middle cylindrical gear 607 and an upper cylindrical gear 608 are rotatably installed on the vertical plate, when the transmission cylindrical gear 606 is located at the upper part of the vertical plate, the transmission cylindrical gear 606 is meshed with the upper cylindrical gear 608, when the transmission cylindrical gear 606 is located at the lower part of the vertical plate, the transmission cylindrical gear 606 is engaged with the intermediate cylindrical gear 607, and the intermediate cylindrical gear 607 and the upper cylindrical gear 608 are transmitted by the reverse transmission belt 602. When the turnover transmission belt 602 rotates, the incomplete gear 603, the middle cylindrical gear 607 and the upper cylindrical gear 608 all rotate, the incomplete gear 603 rotates the lower cylindrical gear 604, the turnover cam 605 rotates when the lower cylindrical gear 604 rotates to make the transmission cylindrical gear 606 descend until the driving conical gear 609 is meshed with the driven conical gear 610 at the lower part of the lead screw 611, at this time, the middle cylindrical gear 607 is meshed with the transmission cylindrical gear 606 to make the driving conical gear 609 rotate, and simultaneously, the driven conical gear 610 rotates to make the lead screw 611 rise upwards and push the stirring mechanism 5 upwards.

Tilting mechanism 6 still includes thread buckle 613, and thread buckle 613 rotates to be installed on the right angle pole, and right angle pole fixed mounting is on mounting panel 1, sets up hollow cylinder in the middle of thread buckle 613, is provided with the inclined plane in the middle of the hollow cylinder, and thread buckle 613 upper portion is connected with torsion spring 614, torsion spring 614 upper end and right angle pole fixed connection. When the screw 611 rises to the inside of the hollow cylinder of the thread button 613, the inclined surface on the screw 611 forms ball screw fit with the inclined surface in the hollow cylinder, at this time, the thread button 613 rotates, the stirring mechanism 5 rotates, so that the stirring mechanism 5 rotates by one hundred eighty degrees, the extrusion disc 503 rotates right above the stirring barrel 501, then the turnover cam 605 is adjusted to rotate, so that the transmission cylindrical gear 606 rises to be meshed with the upper cylindrical gear 608, the driving conical gear 609 is meshed with the driven conical gear 610 above the screw 611, at this time, the screw 611 descends, the stirring mechanism 5 also descends, the extrusion disc 503 continuously enters the stirring barrel 501, and the stirred raw materials are pressed out of the stirring barrel 501 and enter the smelting box 7.

The bevel on the lead screw 611 forms a sliding fit with the bevel in the hollow cylinder.

After the smelting in the smelting box 7 is completed, the sliding plate 701 is pushed to push the raw material into the pellet maker 8. The melting box 7 further comprises a sliding plate 701 for pushing out the melted raw material.

A pellet maker 8 is fixedly installed on the mounting plate 1, the pellet maker 8 includes a pellet forming roller 801 for making dry ceramic pellets, and the pellet forming roller 801 in the pellet maker 8 is activated to perform pellet processing on the raw material.

Claims (3)

1. The utility model provides a nanometer pottery dry grain production and processing is with smelting device, includes mounting panel, conveyer belt, its characterized in that: the device also comprises a weighing mechanism, a grinding mechanism, a stirring mechanism, a turnover mechanism, a smelting box and a particle making machine; the conveying belt is fixedly arranged on the mounting plate;

the weighing mechanism is fixedly arranged on the mounting plate and comprises a weighing box and a gravity sensor, and the gravity sensor is fixedly arranged on a lower end cover of the weighing box; the weighing mechanism further comprises a hopper, the hopper is fixedly arranged on the mounting plate, a pushing electric cylinder and a weighing box are fixedly arranged on the hopper, a pushing plate is fixedly arranged at the extending end of the pushing electric cylinder, the pushing plate is slidably arranged in the hopper, a rack is slidably arranged on the weighing box, the rack is meshed with the opening and closing gear, and the opening and closing gear is fixedly arranged on a shaft of the lower end cover;

the grinding mechanism is fixedly arranged on the mounting plate and comprises a conveyor belt and a grinding roller, and the grinding roller is arranged at one end, close to the grinding mechanism, of the conveyor belt and is used for grinding raw materials; the grinding mechanism further comprises a motor, the motor is fixedly arranged on the mounting plate, an output shaft of the motor is connected with a transmission belt, the transmission belt is arranged on the transmission belt and used for driving the grinding roller to rotate, the pressing cam is fixedly arranged on an intermediate shaft of the grinding roller and is in sliding fit with the pressing plate, and a return spring is arranged between the pressing plate and the transmission belt;

the stirring mechanism is fixedly arranged on the mounting plate and comprises a stirring barrel, an extrusion disc and a stirring plate, wherein the stirring plate is used for stirring raw materials in the stirring barrel, and the extrusion disc is used for extruding the stirred raw materials; the stirring mechanism further comprises a mounting disc, the mounting disc is connected with the extrusion disc through an upright post, a conical gear set is arranged on the stirring barrel and driven by a belt wheel on a conveying belt, a cylindrical gear set is arranged on the mounting disc, the stirring plate is mounted on the cylindrical gear set and meshed with the conical gear set, and the upright post is connected with the turnover mechanism;

the turnover mechanism is fixedly arranged on the mounting plate and is connected with the stirring mechanism, and the turnover mechanism comprises a reversing assembly for converting the positions of the extrusion disc and the stirring plate; the turnover mechanism further comprises a turnover motor and a driving gear set, wherein a turnover driving belt is connected to an output shaft of the turnover motor, the turnover driving belt is connected with the driving gear set, the driving gear set is arranged on the vertical plate, an output end of the driving gear set is meshed with a driven conical gear, the driven conical gear is rotatably arranged on a lead screw, one end of the lead screw is rotatably arranged on the mounting frame, the other end of the lead screw is rotatably arranged with the mounting disc, the mounting frame is fixedly arranged on the mounting plate, the driven conical gear is meshed with the lead screw in a matching manner, and an inclined plane is arranged at the upper end of the lead screw; the driving gear set comprises an incomplete gear, the incomplete gear is fixedly installed with an overturning transmission belt, the incomplete gear is rotatably installed on a vertical plate, the incomplete gear is meshed with a lower cylindrical gear, the lower cylindrical gear is rotatably installed on the vertical plate, an overturning cam is fixedly installed on the lower cylindrical gear, the overturning cam is in sliding fit with an arc-shaped plate on a transmission cylindrical gear, a shaft on which the transmission cylindrical gear is located is slidably installed on the vertical plate, a driving conical gear is fixedly installed on the shaft on which the transmission cylindrical gear is located, the driving conical gear is in meshing fit with a driven conical gear, a middle cylindrical gear and an upper cylindrical gear are rotatably installed on the vertical plate, when the transmission cylindrical gear is located at the upper part of the vertical plate, the transmission cylindrical gear is meshed with the upper cylindrical gear, when the transmission cylindrical gear is located at the lower part of the vertical plate, the transmission cylindrical gear is meshed with the middle cylindrical gear, and the middle cylindrical gear and the upper cylindrical gear are transmitted through an overturning transmission belt;

tilting mechanism still include the screw thread and detain, the screw thread detain and rotate and install on right angle pole, right angle pole fixed mounting on the mounting panel, the screw thread detain in the middle of set up hollow cylinder, hollow cylinder in the middle of be provided with the inclined plane, the screw thread detain the upper portion and be connected with torsion spring, torsion spring upper end and right angle pole fixed connection

The smelting box is fixedly arranged on the mounting plate and used for smelting raw materials;

the particle making machine is fixedly arranged on the mounting plate and comprises a particle forming roller for making dry ceramic particles.

2. The melting device for producing and processing the dry nano-ceramic particles as claimed in claim 1, wherein: the inclined plane on the lead screw and the inclined plane in the hollow cylinder form sliding fit.

3. The melting device for producing and processing the dry nano-ceramic particles as claimed in claim 1, wherein: the smelting box also comprises a sliding plate for pushing out the smelted raw materials.

Images