CN113105265B

CN113105265B - Dislocation formula carborundum honeycomb ceramic carrier cross-section plugging device

Info

Publication number: CN113105265B
Application number: CN202110265179.3A
Authority: CN
Inventors: 李金宝
Original assignee: Zaozhuang Shuncheng Abrasive Sales Co ltd
Current assignee: Zaozhuang Shuncheng Abrasive Sales Co ltd
Priority date: 2021-03-11
Filing date: 2021-03-11
Publication date: 2023-03-31
Anticipated expiration: 2041-03-11
Also published as: CN113105265A

Abstract

The invention relates to the field of silicon carbide, in particular to a dislocation type silicon carbide honeycomb ceramic carrier section plugging device. The technical problem is as follows: provides a dislocation type silicon carbide honeycomb ceramic carrier section plugging device. The technical scheme is as follows: a dislocation type silicon carbide honeycomb ceramic carrier section plugging device comprises a working machine bed plate, a supporting foot frame, an installation top frame, an operation control screen, a standing solidification transfer system and the like; the upper part of the supporting foot stand is welded with a working machine tool plate. The invention realizes the plugging treatment of the silicon carbide honeycomb ceramic carrier, automatically fixes and positions the honeycomb ceramic carrier, then performs interval plugging on the section holes of the ceramic honeycomb carrier in an interval extrusion mode, and extends into the corresponding holes from the opening of the section at the other side of the plugging hole to extrude and shape the pug so as to prevent the pug from natural flowing deformation under gravity.

Description

Dislocation formula carborundum honeycomb ceramic carrier cross-section plugging device

Technical Field

The invention relates to the field of silicon carbide, in particular to a dislocation type silicon carbide honeycomb ceramic carrier section plugging device.

Background

Silicon carbide is an inorganic substance, has a chemical formula of SiC, and is prepared by smelting quartz sand, petroleum coke (or coal coke), wood chips (salt is required when green silicon carbide is produced) and other raw materials in a resistance furnace at high temperature.

At present, in chinese patent CN104844272A in the prior art, which is named as "wall-flow honeycomb ceramic carrier blank hole blocking method" in the patent of the prior patent application No. CN200610106776.7, a film is used to wrap two bad cross sections of a wall-flow honeycomb ceramic carrier, holes are formed in the film in a crossed manner, the film holes on the two cross sections are not communicated with each other, hole blocking mud is extruded in an extrusion manner to form a channel with a closed tail end, and gas to be filtered enters the wall-flow honeycomb ceramic carrier blank from an opening at one end and then enters adjacent holes to be discharged after being filtered through a hole wall. The technical scheme of the invention mainly has the following defects: 1. because the honeycomb ceramics have a large number of meshes and small holes, a film opening and blocking method is adopted, the opening process is easy to operate by mistake, and the blocking yield is low; 2. the extrusion method is simple and crude, the pug entering the pore canal of the billet is not uniform, the billet is easy to crack, and the pug is easy to loosen; 3. the plugging efficiency is low, and the continuous production operation can not be realized, and the method and the device for plugging the end face of the silicon carbide honeycomb ceramic carrier are disclosed, wherein a special plugging die matched with the silicon carbide honeycomb ceramic carrier is adopted, so that the plugging efficiency and the plugging effect of the two end faces of the silicon carbide honeycomb ceramic carrier can be effectively improved, and the rate of finished products of plugging the silicon carbide honeycomb ceramic carrier is improved; on the other hand, the problems of cracking of a silicon carbide honeycomb ceramic carrier blank body, looseness of mud in a pore channel, unevenness of mud in the pore channel plugging and the like after plugging are solved by matching with special plugging mud, but improvement and design are mainly made for squeezing mud into a hole on the cross section of one side of the silicon carbide honeycomb ceramic carrier, but other designs are not made for the treatment after squeezing;

after the pug is extruded into a hole in one side of the silicon carbide honeycomb ceramic carrier, the pug has certain fluidity due to the fact that the pug contains water, and further when the silicon carbide honeycomb ceramic carrier is in a horizontal state, the pug in the silicon carbide honeycomb ceramic carrier can slowly flow to be horizontal due to gravity, so that holes plugged by the pug are in a gap.

In order to solve the problems, a dislocation type silicon carbide honeycomb ceramic carrier section plugging device is provided.

Disclosure of Invention

In order to overcome wherein behind the pug by crowded carborundum honeycomb ceramic carrier one side hole, this moment because contain moisture in the pug, it has certain mobility, and then when carborundum honeycomb ceramic carrier horizontality, its inside pug can receive gravity to carry out slow flow and tend to the level, the hole that leads to the pug shutoff appears the space, when carborundum honeycomb ceramic carrier is placed vertically again and is stood, the pug can be followed the level and slowly flow to vertical state again and pile up and block up the hole, but when the first pug flows to horizontal state, partial pug can adhere to the position of standard pug length upside, lead to the inboard cross-section of pug to be the inclined plane, hole pug one side edge is thinner promptly, thin part can the fracture and drop after experiencing external force, influence follow-up shortcoming, the technical problem: provides a dislocation type silicon carbide honeycomb ceramic carrier section plugging device.

The technical scheme is as follows: a dislocation formula carborundum honeycomb ceramic carrier cross-section plugging device, including:

a working machine bed plate;

the upper part of the supporting foot stand is welded with the working machine tool plate;

installing a top frame, and welding the lower part of the installing top frame with a working machine tool plate;

the operation control screen is connected with the mounting top frame;

the standing solidification transfer system is connected with the working machine tool plate below the standing solidification transfer system;

the lower part of the dislocation unidirectional plugging system is connected with a working machine tool plate;

and the fixed-length extrusion system in the hole is connected with the mounting top frame above the fixed-length extrusion system in the hole.

Preferably, the standing coagulation transfer system comprises:

the lower part of the motor frame is connected with a working machine tool plate through bolts;

the power motor is in bolted connection with the motor frame;

the axle center of the first transmission wheel is fixedly connected with the output shaft of the power motor;

the axle center of the first rotating shaft rod is fixedly connected with the first driving wheel;

the axle center of the second driving wheel is fixedly connected with the first rotating shaft rod;

the first bearing frame plate is rotatably connected with the first rotating shaft rod, and the lower part of the first bearing frame plate is welded with the motor frame;

the outer ring surface of the third driving wheel is in transmission connection with the first driving wheel through a belt, and the third driving wheel is in rotation connection with the first bearing frame plate;

the axle center of the first half gear is fixedly connected with the third transmission wheel;

the first flat gear is meshed with the first half gear;

the axle center of the first torsion spring rotating shaft seat is fixedly connected with the first flat gear;

the first fixed shaft column is rotatably connected with the first torsion spring rotating shaft seat, and the lower part of the first fixed shaft column is fixedly connected with a working machine tool plate;

the first transfer deflector rod is fixedly connected with the first torsion spring rotating shaft seat;

a fourth transmission wheel;

the second rotating shaft rod is fixedly connected with the fourth driving wheel;

the second bearing frame plate is rotatably connected with the second rotating shaft rod, and the lower part of the second bearing frame plate is welded with the motor frame;

the axis of the fifth driving wheel is fixedly connected with the second rotating shaft rod;

the outer ring surface of the sixth driving wheel is in transmission connection with the fifth driving wheel through a belt, and the axis of the sixth driving wheel is in rotary connection with the second bearing frame plate;

the axle center of the second half gear is fixedly connected with the sixth driving wheel;

the second flat gear is meshed with the second half gear;

the axle center of the second torsion spring rotating shaft seat is fixedly connected with the second flat gear;

the second fixed shaft column is rotatably connected with the second torsion spring rotating shaft seat, and the lower part of the second fixed shaft column is fixedly connected with the working machine tool plate;

the second transfer deflector rod is fixedly connected with the second torsion spring rotating shaft seat;

the lower part of the electric transmission mechanism is connected with the working machine tool plate;

the lower part of the bearing and transferring long plate is fixedly connected with a working machine tool plate;

the anti-sticking bearing transfer cloth is contacted with the bearing transfer long plate;

the winding control roller is wound with anti-sticking bearing transfer cloth on the outer surface and is rotationally connected with the working machine tool plate;

the output shaft of the control motor is fixedly connected with the winding control roller, and the lower part of the control motor is connected with a working machine tool plate through a bolt;

the outer ring surface of the seventh driving wheel is in transmission connection with the fourth driving wheel through a belt, and the axle center of the seventh driving wheel is in rotary connection with the second bearing frame plate;

the axle center of the fourth flat gear is fixedly connected with the seventh transmission wheel;

the fifth flat gear is meshed with the fourth flat gear;

the shaft center of the eighth driving wheel is fixedly connected with the fifth flat gear, the shaft center of the eighth driving wheel is rotatably connected with the second bearing frame plate, and the outer ring surface of the eighth driving wheel is in transmission connection with the second driving wheel through a belt;

and the lower part of the transfer table is welded with a working machine tool plate.

Preferably, the malposition unidirectional plugging system comprises:

the lower part of the first mounting bearing frame is welded with a working machine tool plate;

the lower part of the first pug extruder is in bolted connection with the first mounting bearing frame;

the first extrusion cylinder is connected with the first pug extruder;

the first extrusion inner inserting positioning pipe is connected with the first extrusion barrel;

the lower part of the first electric rotating shaft frame seat is connected with a working machine tool plate through bolts;

the first connecting seat is connected with the first electric rotating shaft frame seat;

the lower part of the first opening and closing electric control shaft seat is connected with the first connecting seat platform through a bolt;

the first semicircular clamping ring is connected with the first opening and closing electric control shaft seat;

the second semicircular clamping ring is connected with the first opening and closing electric control shaft seat;

the lower part of the second mounting bearing frame is welded with a working machine tool plate;

the lower part of the second pug extruder is in bolted connection with the second mounting bearing frame;

the second extrusion cylinder is connected with the second pug extruder;

the second extrusion inner insertion positioning pipe is connected with the second extrusion barrel;

the lower part of the second electric rotating shaft frame seat is connected with a working machine tool plate through bolts;

the lower part of the second connecting seat platform is connected with a second electric rotating shaft frame seat;

the lower part of the second opening and closing electric control shaft seat is connected with a second connecting seat platform through a bolt;

the third semicircular clamping ring is connected with the second opening and closing electric control shaft seat;

and the fourth semicircular clamping ring is connected with the second opening and closing electric control shaft seat.

Preferably, the fixed-length extrusion system in the hole comprises:

the upper part of the first electric lifting column is connected with the mounting top frame through a bolt;

the upper part of the second electric lifting column is connected with the mounting top frame through a bolt;

the upper part of the long mounting plate is sequentially connected with the first electric lifting column and the second electric lifting column through bolts;

the upper part of the electric sliding rail is connected with the mounting long plate through a bolt;

the electric sliding seat is connected with the electric sliding rail in a sliding manner;

the damping rotating shaft seat is fixedly connected with the electric sliding seat;

the connecting shaft column is rotatably connected with the damping rotating shaft seat;

the axle center of the third flat gear is fixedly connected with the connecting shaft column;

the upper part of the fixed lantern ring is fixedly connected with the connecting shaft column;

the reverse positioning insertion rod group is sleeved with the fixed lantern ring;

and the incomplete rack rail plate is welded with the long mounting plate above the incomplete rack rail plate.

Preferably, two winding control rollers and two control motors are arranged.

Preferably, the toothed part at the front end of the incomplete rack rail plate can drive the third flat gear to rotate by one hundred eighty degrees.

Preferably, after the silicon carbide honeycomb ceramic carrier is fixed, the straight tubes of the first extrusion interpolation positioning tube and the straight tubes of the second extrusion interpolation positioning tube are aligned with the holes of the silicon carbide honeycomb ceramic carrier, and the straight tubes of the first extrusion interpolation positioning tube and the straight tubes of the second extrusion interpolation positioning tube are alternately arranged in the front-rear direction.

Compared with the prior art, the invention has the following advantages:

firstly, in order to solve the problem that after the pug is extruded into a hole on one side of a silicon carbide honeycomb ceramic carrier, the pug contains water and has certain fluidity, so that when the silicon carbide honeycomb ceramic carrier is in a horizontal state, the pug in the silicon carbide honeycomb ceramic carrier slowly flows to be horizontal under the action of gravity, and the hole blocked by the pug is gapped;

secondly, designing a standing solidification transfer system, a dislocation one-way plugging system and a hole fixed length extrusion system, when in use, firstly fixing the silicon carbide ceramic carrier to the dislocation one-way plugging system, then plugging pug into the hole of the section of one side of the silicon carbide honeycomb ceramic carrier by the dislocation one-way plugging system, simultaneously controlling the hole fixed length extrusion system to be inserted into the corresponding hole from the inside of the hole of the section of the other side of the silicon carbide honeycomb ceramic carrier, pressurizing and shaping pug from the other side, then controlling the dislocation one-way plugging system to convey the silicon carbide ceramic carrier to the standing solidification transfer system for standing and cooling, and then conveying again to the dislocation one-way plugging system, namely plugging the corresponding hole of the section of the other side with pug, and pressurizing and shaping again by the hole fixed length extrusion system;

thirdly, the plugging treatment of the silicon carbide honeycomb ceramic carrier is realized, the honeycomb ceramic carrier is automatically fixed and positioned, then the section holes of the ceramic honeycomb carrier are plugged at intervals in an interval extrusion mode, the holes extend into corresponding holes from the opening of the section of the other side of the plugging hole to extrude and shape the mud, the mud is prevented from being deformed due to gravity natural flow, the silicon carbide honeycomb ceramic carrier which is plugged at one side is automatically laid flat to be cooled and solidified, and the section of the other side is automatically plugged in a staggered mode again.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic structural diagram of a static coagulation transfer system according to the present invention;

FIG. 3 is a schematic structural diagram of the malposition unidirectional plugging system of the present invention;

fig. 4 is a schematic structural view of the fixed-length extrusion system in the hole.

Description of reference numerals: 1_ working machine bedplate, 2_ supporting foot stool, 3_ mounting top frame, 4_ running control screen, 5_ static solidification transfer system, 6_ dislocation one-way plugging system, 7_ in-hole fixed length extrusion system, 501_ motor frame, 502_ power motor, 503_ first transmission wheel, 504_ first rotating shaft rod, 505_ second transmission wheel, 506_ first bearing frame plate, 507_ third transmission wheel, 508_ first half gear, 509_ first flat gear, 5010_ first torsion spring rotating shaft seat, 5011_ first fixed shaft column, 5012_ first transfer lever, 5013_ fourth transmission wheel, 5014_ second rotating shaft rod, 5015_ second bearing frame plate, 5016_ fifth transmission wheel, 5017_ sixth transmission wheel, 5018_ second half gear, 5019_ second flat gear, 5020_ second torsion spring rotating shaft seat, 5021_ second fixed shaft column, 5022_ second transfer lever, and shifting lever 3_ electric transmission mechanism, 5024_ load bearing and transferring long plate, 5025_ anti-sticking load bearing and transferring cloth, 5026_ rolling control roller, 5027_ control motor, 5028_ seventh driving wheel, 5029_ fourth flat gear, 5030_ fifth flat gear, 5031_ eighth driving wheel, 5032_ transfer table, 601_ first mounting bracket, 602_ first pug extruder, 603_ first extrusion cylinder, 604_ first extrusion interpolation positioning pipe, 605_ first electric rotating shaft holder, 606_ first engagement seat, 607_ first opening and closing electric control shaft seat, 608_ first semicircular clamp ring, 609_ second semicircular clamp ring, 6010_ second mounting bracket, 6011_ second pug extruder, 2_ second extrusion cylinder, 6013_ second extrusion interpolation positioning pipe, 6014_ second electric rotating shaft holder, 6015_ second engagement seat, 6016_ second opening and closing electric control shaft seat, 6017_ third semicircular clamp ring, 6018_ fourth semicircular clamp ring, 701_ first electric lifting column, 702_ second electric lifting column, 703_ mounting long plate, 704_ electric sliding rail, 705_ electric sliding seat, 706_ damping rotating shaft seat, 707_ connecting shaft column, 708_ third gear, 709_ fixing lantern ring, 7010_ reverse positioning inserted bar group, 7011_ incomplete rack rail plate.

Detailed Description

The following description is only a preferred embodiment of the present invention, and does not limit the scope of the present invention.

Example 1

A dislocation type silicon carbide honeycomb ceramic carrier section plugging device is shown in figures 1-4 and comprises a working machine bed plate 1, a supporting foot rest 2, an installation top frame 3, an operation control screen 4, a standing solidification transfer system 5, a dislocation unidirectional plugging system 6 and a fixed length extrusion system 7 in a hole; the upper part of the supporting foot stand 2 is welded with the bed plate 1 of the working machine; the lower part of the mounting top frame 3 is welded with the working machine bed plate 1; the operation control screen 4 is connected with the mounting top frame 3; the lower part of the standing solidification transfer system 5 is connected with a working machine bed plate 1; the lower part of the dislocation unidirectional plugging system 6 is connected with the working machine bed plate 1; the upper part of the fixed-length extrusion system 7 in the hole is connected with the installation top frame 3.

The working process is as follows: when the dislocation type silicon carbide honeycomb ceramic carrier section plugging device is used, the device is stably fixed to a working plane, then a power supply is connected externally, a control device of an operation control screen 4 is manually opened to operate, the silicon carbide ceramic carrier is fixed to a dislocation one-way plugging system 6, then the dislocation one-way plugging system 6 plugs pug into a hole in one side section of the silicon carbide honeycomb ceramic carrier, meanwhile, a control hole inner fixed-length extrusion system 7 is inserted into a corresponding hole from the inside of the hole in the other side section of the silicon carbide honeycomb ceramic carrier, the pug is pressurized from the other side, then the dislocation one-way plugging system 6 is controlled to convey the silicon carbide ceramic carrier to a standing solidification transfer system 5 for standing and cooling, then convey the unidirectional plugging system 6 of dislocation again, carry out the pug shutoff to the corresponding hole of opposite side cross-section promptly, and pressurize moulding again through downthehole fixed length extrusion system 7, realized the shutoff of carborundum honeycomb ceramic carrier and handled, carry out automatic fixed position to honeycomb ceramic carrier, then carry out interval shutoff to the cross-section hole of ceramic honeycomb carrier through the mode of interval extrusion, and stretch into inside the corresponding hole from the other side cross-section opening part of shutoff hole and extrude moulding to the pug and prevent that the pug from receiving gravity natural flow deformation, the carborundum honeycomb ceramic carrier that one side shutoff was accomplished is kept flat automatically and is cooled and solidify, carry out the effect of automatic shutoff once more of dislocation to the other side cross-section.

The standing solidification transfer system 5 comprises a motor frame 501, a power motor 502, a first transmission wheel 503, a first rotating shaft rod 504, a second transmission wheel 505, a first bearing frame plate 506, a third transmission wheel 507, a first half gear 508, a first flat gear 509, a first torsion spring rotating shaft seat 5010, a first fixed shaft column 5011, a first transfer shift lever 5012, a fourth transmission wheel 5013, a second rotating shaft rod 5014, a second bearing frame plate 5015, a fifth transmission wheel 5016, a sixth transmission wheel 5017, a second half gear 5018, a second flat gear 5019, a second torsion spring rotating shaft seat 5020, a second fixed shaft column 5021, a second transfer lever 5022, an electric transmission mechanism 5023, a bearing transfer long plate 5024, anti-sticking bearing transfer cloth 5025, a winding control roller 5026, a control motor 5027, a seventh transmission wheel 5028, a fourth flat gear 5029, a fifth flat gear 5030, an eighth flat gear 5031 and a transfer platform 5032; the lower part of the motor frame 501 is connected with a working machine bed plate 1 through bolts; the power motor 502 is connected with the motor frame 501 through bolts; the axle center of the first driving wheel 503 is fixedly connected with the output shaft of the power motor 502; the axis of the first rotating shaft rod 504 is fixedly connected with the first driving wheel 503; the axle center of the second driving wheel 505 is fixedly connected with the first rotating shaft rod 504; the first bearing frame plate 506 is rotatably connected with the first rotating shaft rod 504, and the lower part of the first bearing frame plate 506 is welded with the motor frame 501; the outer ring surface of the third driving wheel 507 is in transmission connection with the first driving wheel 503 through a belt, and the third driving wheel 507 is in rotation connection with the first bearing frame plate 506; the axle center of the first half gear 508 is fixedly connected with a third driving wheel 507; the first spur gear 509 is meshed with the first half gear 508; the axle center of the first torsion spring rotating shaft seat 5010 is fixedly connected with the first flat gear 509; the first fixed shaft column 5011 is rotatably connected with the first torsion spring rotating shaft seat 5010, and the lower part of the first fixed shaft column 5011 is fixedly connected with the working machine bedplate 1; the first transfer shift lever 5012 is fixedly connected with the first torsion spring rotating shaft base 5010; the second rotating shaft 5014 is fixedly connected with a fourth transmission wheel 5013; the second bearing frame plate 5015 is in rotating connection with the second rotating shaft 5014, and the lower side of the second bearing frame plate 5015 is welded with the motor frame 501; the axle center of the fifth transmission wheel 5016 is fixedly connected with the second rotating shaft 5014; the outer ring surface of the sixth transmission wheel 5017 is in transmission connection with the fifth transmission wheel 5016 through a belt, and the axle center of the sixth transmission wheel 5017 is in rotation connection with the second bearing frame plate 5015; the axle center of the second half gear 5018 is fixedly connected with a sixth transmission wheel 5017; the second spur gear 5019 meshes with the second half gear 5018; the axis of the second torsion spring rotating shaft seat 5020 is fixedly connected with the second flat gear 5019; the second fixed shaft column 5021 is in rotary connection with a second torsion spring rotating shaft seat 5020, and the lower part of the second fixed shaft column 5021 is fixedly connected with a working machine bedplate 1; the second transfer shift lever 5022 is fixedly connected with the second torsion spring rotating shaft seat 5020; the lower part of the electric transmission mechanism 5023 is connected with the working machine bed plate 1; the lower part of the bearing transfer long plate 5024 is fixedly connected with a bed plate 1 of the working machine; the anti-sticking bearing transfer cloth 5025 is in contact with the bearing transfer long plate 5024; an anti-sticking bearing transfer cloth 5025 is wound on the outer surface of the winding control roller 5026, and the winding control roller 5026 is in rotating connection with the machine tool bed plate 1; an output shaft of a control motor 5027 is fixedly connected with a winding control roller 5026, and the lower part of the control motor 5027 is connected with a working machine bed plate 1 through a bolt; the outer annular surface of the seventh driving wheel 5028 is in transmission connection with the fourth driving wheel 5013 through a belt, and the axis of the seventh driving wheel 5028 is in rotational connection with the second bearing frame plate 5015; the axis of the fourth flat gear 5029 is fixedly connected with a seventh transmission wheel 5028; the fifth spur gear 5030 meshes with the fourth spur gear 5029; the axle center of the eighth driving wheel 5031 is fixedly connected with the fifth flat gear 5030, the axle center of the eighth driving wheel 5031 is rotatably connected with the second bearing frame plate 5015, and the outer annular surface of the eighth driving wheel 5031 is in transmission connection with the second driving wheel 505 through a belt; the lower part of the transfer table 5032 is welded with the working machine bed plate 1.

After the dislocation unidirectional plugging system 6 completes plugging of the holes on the cross section at one side of the silicon carbide honeycomb ceramic carrier, the silicon carbide honeycomb ceramic carrier is controlled to be horizontally placed on the upper surface of the electric transmission mechanism 5023, then the power of the electric transmission mechanism 5023 is controlled to be switched on, namely, the electric transmission mechanism 5023 drives the silicon carbide honeycomb ceramic carrier to move backwards, at the moment, the power motor 502 drives the first driving wheel 503 to rotate, then the first driving wheel 503 drives the first rotating shaft rod 504 and the second driving wheel 505 to rotate, then the second driving wheel 505 drives the eighth driving wheel 5031 to rotate, further the eighth driving wheel 5031 drives the fifth flat gear 5030 to rotate, then the fifth flat gear 5030 drives the fourth flat gear 5029 to rotate, further the fourth flat gear 5029 drives the seventh driving wheel 5028 to rotate, then the seventh driving wheel 5028 drives the fourth driving wheel 5013 to rotate, then the fourth driving wheel 5013 drives the second rotating shaft 5014 to rotate, then the second rotating shaft 5014 drives the fifth driving wheel 5016 to rotate, further the fifth driving wheel 5016 drives the sixth driving wheel 5017 to rotate, further the sixth driving wheel 5017 drives the second half gear 5018 to rotate, then the second half gear 5018 drives the second flat gear 5019 to rotate, namely the second flat gear 5019 drives the second torsion spring spindle bracket 5020 to rotate, namely the second torsion spring spindle bracket 5020 drives the second transfer deflector 5022 to be shifted leftwards, after the electric transmission mechanism 5023 drives the silicon carbide honeycomb ceramic carrier to move to the front side of the second transfer deflector 5022, the second transfer deflector 5022 shifts the silicon carbide honeycomb ceramic carrier at the top of the electric transmission mechanism 5023 to the upper surface of the anti-sticking bearing transfer cloth 5025 above the left bearing transfer long plate 5024, and then the silicon carbide honeycomb ceramic carrier is manually turned upwards and downwards, after the second half gear 5018 is disengaged from the second flat gear 5019, that is, the second torsion spring spindle 5020 drives the second transfer lever 5022 to move to the right through its elasticity to reset, then the power of the control motor 5027 is controlled to be turned on, that is, the control motor 5027 rotates to drive the winding control roller 5026 to rotate, that is, the winding control roller 5026 drives the anti-sticking bearing transfer cloth 5025 to pull forward, then the anti-sticking bearing transfer cloth 5025 drives the silicon carbide honeycomb ceramic carrier at the top of the anti-sticking bearing transfer cloth 5025 to move forward for a certain distance, then the power of the control motor 5027 is controlled to be turned off, that is, the silicon carbide honeycomb ceramic carrier stands still and solidifies, after the next silicon carbide honeycomb ceramic is adhered to the top of the anti-sticking bearing transfer cloth 5025, the anti-sticking bearing transfer cloth 5025 is controlled again to move forward for a certain distance, and then the silicon carbide ceramic carrier moves forward, and the operations are repeated in sequence, when the first silicon carbide ceramic carrier at the foremost side of the top of the anti-sticking bearing transfer cloth 5025 moves to the foremost side, the standing time of the first silicon carbide ceramic carrier is enough, the first driving wheel 503 drives the third driving wheel 507 to rotate, the third driving wheel 507 drives the first half gear 508 to rotate, namely the first half gear 508 drives the first pinion 509 to rotate, the first pinion 509 drives the first torsion spring spindle base 5010 to rotate, the first torsion spring spindle base 5010 drives the first transfer shift lever 5012 to shift leftwards, the first transfer shift lever 5012 shifts the first silicon carbide ceramic carrier at the foremost side of the top of the anti-sticking bearing transfer cloth 5025 leftwards to the top surface of the transfer table 5032, and then the dislocation unidirectional plugging system 6 can be controlled to clamp the silicon carbide ceramic carrier to plug the hole at the other side section, the silicon carbide honeycomb ceramic carrier is stood, the mud on the inner side of the silicon carbide honeycomb ceramic carrier is preliminarily solidified, and the silicon carbide honeycomb ceramic carrier is transferred.

The staggered unidirectional plugging system 6 comprises a first mounting bearing frame 601, a first pug extruder 602, a first extruding cylinder 603, a first extruding and inserting positioning pipe 604, a first electric rotating shaft frame seat 605, a first joining seat stand 606, a first opening and closing electric control shaft seat 607, a first semicircular clamping ring 608, a second semicircular clamping ring 609, a second mounting bearing frame 6010, a second pug extruder 6011, a second extruding cylinder 6012, a second extruding and inserting positioning pipe 6013, a second electric rotating shaft frame seat 6014, a second joining seat stand 6015, a second opening and closing electric control shaft seat 6016, a third semicircular clamping ring 6017 and a fourth semicircular clamping ring 6018; the lower part of the first mounting bearing frame 601 is welded with the working machine bed plate 1; the lower part of the first pug extruder 602 is connected with a first mounting bearing frame 601 through bolts; the first extrusion cylinder 603 is connected with the first pug extruder 602; the first extrusion inner inserting positioning pipe 604 is connected with the first extrusion cylinder 603; the lower part of the first electric rotating shaft frame seat 605 is connected with a working machine bed plate 1 through bolts; the first engaging base 606 is connected to the first electric spindle base 605; the lower part of the first opening and closing electric control shaft seat 607 is connected with a first connecting seat stand 606 through a bolt; the first semicircular clamping ring 608 is connected with a first opening and closing electric control shaft seat 607; the second semicircular clamping ring 609 is connected with the first opening and closing electric control shaft seat 607; the lower part of the second mounting bearing frame 6010 is welded with the working machine bed plate 1; the lower part of the second pug extruder 6011 is bolted to a second mounting bearing frame 6010; the second extrusion barrel 6012 is connected with a second pug extruder 6011; the second extrusion inner inserting positioning pipe 6013 is connected with a second extrusion barrel 6012; the lower part of the second electric rotating shaft frame seat 6014 is in bolt connection with the working machine bed plate 1; the lower part of the second connecting seat 6015 is connected with a second electric rotating shaft frame 6014; the lower part of the second opening and closing electric control shaft seat 6016 is in bolted connection with a second connecting seat 6015; the third semicircular clamping ring 6017 is connected with a second opening and closing electric control shaft seat 6016; the fourth semicircular clamping ring 6018 is connected to the second electric control shaft seat 6016.

Firstly, a second opening and closing electric control shaft seat 6016 is controlled to drive a third semicircular clamp ring 6017 and a fourth semicircular clamp ring 6018 to be combined to clamp and fix a silicon carbide honeycomb ceramic carrier to be subjected to plugging, namely, a section hole of the honeycomb ceramic carrier just corresponds to a second extrusion interpolation positioning pipe 6013, then a second pug extruder 6011 is controlled to extrude pug in the second extrusion barrel 6012, the pug enters the hole of the silicon carbide honeycomb ceramic carrier through the second extrusion interpolation positioning pipe 6013 to extrude a section of excess standard length pug, then an in-hole fixed length extrusion system 7 is controlled to insert from an opening of the section of the other side of the corresponding plugging hole of the silicon carbide honeycomb ceramic carrier to extrude and shape the left side of the pug, and after the molding is finished, a second electric rotating shaft frame seat 6014 is controlled to rotate ninety degrees anticlockwise, that is, the second electric rotating shaft holder 6014 drives the second engaging holder 6015, the second open-close electric control shaft holder 6016, the third semicircular clamp ring 6017, and the fourth semicircular clamp ring 6018 to rotate leftward, that is, the section of the silicon carbide honeycomb ceramic carrier after the second electric rotating shaft holder 6014 rotates ninety degrees is parallel to the top surface of the electric transmission mechanism 5023, then the second open-close electric control shaft holder 6016 is controlled to drive the third semicircular clamp ring 6017 and the fourth semicircular clamp ring 6018 to open, then the second electric rotating shaft holder 6014 is controlled to rotate clockwise ninety degrees again to complete the resetting, after the treatment of the standing and solidifying system 5, the silicon carbide honeycomb ceramic carrier is transferred to the top surface of the transferring holder 5032, then the first electric rotating shaft holder 605 is controlled to rotate clockwise ninety degrees, then the first open-close electric control shaft holder 607 is controlled to drive the first semicircular clamp ring 608 and the second semicircular clamp ring 609 to approach each other to clamp and fix the silicon carbide honeycomb ceramic carrier on the top surface of the transferring holder 5032, then, the first electric rotating shaft holder 605 is controlled to rotate anticlockwise for ninety degrees to complete resetting, at this time, the silicon carbide right side is sealed at intervals, namely, the right side of one half of the holes is sealed, the left side section opening of the left side non-sealed hole is opposite to the first extrusion interpolation positioning pipe 604, then the first pug extruder 602 is controlled to extrude pug to the inner side of the left side hole of the silicon carbide honeycomb ceramic carrier through the first extrusion cylinder 603 and the first extrusion interpolation positioning pipe 604, the fixed-length extrusion system 7 in the hole is controlled to be inserted from the other side section opening of the left side sealed hole corresponding to the silicon carbide honeycomb ceramic carrier to extrude and shape the right side of the pug again, after the shaping sealing is completed, the first electric rotating shaft holder 605 is controlled to rotate clockwise for ninety degrees again, then the first opening and closing electric control shaft seat 607 is controlled to drive the first semicircular clamp ring 608 and the second semicircular clamp ring 609 to open, then the silicon carbide honeycomb ceramic after the sealing is sealed is placed on the top surface of the transfer table 2 again, then the silicon carbide honeycomb ceramic after the sealing is manually turned over for one hundred eighty degrees again, the top surface of the silicon carbide honeycomb is taken away from the top surface of the transfer table 2 to be left, and the silicon carbide ceramic is solidified, and the silicon carbide honeycomb ceramic after the sealing is left side of the silicon carbide honeycomb is sealed honeycomb is completed.

The fixed-length extrusion system 7 in the hole comprises a first electric lifting column 701, a second electric lifting column 702, a mounting long plate 703, an electric sliding rail 704, an electric sliding seat 705, a damping rotating shaft seat 706, a connecting shaft column 707, a third pinion 708, a fixed lantern ring 709, a reverse positioning insertion rod group 7010 and an incomplete rack rail plate 7011; the upper part of the first electric lifting column 701 is connected with the mounting top frame 3 through a bolt; the upper part of the second electric lifting column 702 is connected with the mounting top frame 3 through a bolt; the upper part of the installation long plate 703 is sequentially connected with a first electric lifting column 701 and a second electric lifting column 702 through bolts; the upper part of the electric slide rail 704 is connected with the mounting long plate 703 through bolts; the electric sliding base 705 is connected with the electric sliding rail 704 in a sliding manner; the damping rotating shaft seat 706 is fixedly connected with the electric sliding seat 705; the connecting shaft column 707 is rotationally connected with the damping rotating shaft seat 706; the axle center of the third flat gear 708 is fixedly connected with the connecting shaft column 707; the upper part of the fixed lantern ring 709 is fixedly connected with the connecting shaft column 707; the reverse positioning insertion rod group 7010 is sleeved with the fixed lantern ring 709; the upper part of the incomplete rack rail plate 7011 is welded with the installation long plate 703.

After the silicon carbide honeycomb ceramic carrier is fixed to the inner sides of a third semicircular clamping ring 6017 and a fourth semicircular clamping ring 6018, a second pug extruder 6011 is controlled to extrude into a right hole of the section of the silicon carbide honeycomb ceramic carrier, then the electric slide rail 704 is controlled and driven to drive an electric slide carriage 705 to move rightwards, then the electric slide carriage 705 drives a damping rotating shaft seat 706, a connecting shaft column 707, a third spur gear 708, a fixed lantern ring 709 and a reverse positioning insertion rod group 7010 to move rightwards, namely the reverse positioning insertion rod group 7010 moves rightwards and is inserted into a hole where pug is extruded into the right side, the left side of the pug is extruded and molded, after the silicon carbide honeycomb ceramic carrier is fixed to the inner sides of a first semicircular clamping ring 608 and a second semicircular clamping ring 609, a first pug extruder 602 is controlled to extrude into a left hole of the section of the silicon carbide honeycomb ceramic carrier, at this moment, the electric slide rail 704 is controlled to drive the electric slide carriage 705 to move leftwards, then the electric slide carriage 705 drives the damping rotating shaft base 706, the connecting shaft column 707, the third pinion 708, the fixed lantern ring 709 and the reverse positioning insertion rod group 7010 to move leftwards, the third pinion 708 is meshed with the incomplete rack rail plate 7011 in the movement process, then the incomplete rack rail plate 7011 drives the third pinion 708 to rotate, then the third pinion 708 drives the connecting shaft column 707, the fixed lantern ring 709 and the reverse positioning insertion rod group 7010 to rotate for one hundred eighty degrees, then the reverse positioning insertion rod group 7010 is inserted from a hole which is not plugged on the right side of the silicon carbide honeycomb ceramic in a left-right reverse direction, then corresponding mud on the left side is extruded and molded, and the extrusion and molding of the silicon carbide honeycomb ceramic carrier mud are completed.

Wherein, rolling control roller 5026 and control motor 5027 all are provided with two.

So that the two groups of winding control rollers 5026 and the control motor 5027 on the front side and the back side can drive the anti-sticking bearing transfer cloth 5025 to keep tight in the forward or backward movement process.

The toothed part at the front end of the incomplete rack rail plate 7011 can drive the third flat gear 708 to rotate one hundred eighty degrees.

So that the automatic flipping over can be performed when the reverse orientation plunger set 7010 is moved to the left or to the right.

After the silicon carbide honeycomb ceramic carrier is fixed, the straight pipes of the first extrusion inner insertion positioning pipe 604 and the straight pipes of the second extrusion inner insertion positioning pipe 6013 are aligned with the holes of the silicon carbide honeycomb ceramic carrier, and the straight pipes of the first extrusion inner insertion positioning pipe 604 and the straight pipes of the second extrusion inner insertion positioning pipe 6013 are alternately arranged in the front-rear direction.

So that after the second extruded and inserted positioning tube 6013 is used for plugging holes on the right side of the silicon carbide honeycomb ceramic carrier at intervals, the holes which are not plugged on the right side can be plugged from the left side by the first extruded and inserted positioning tube 604, and further the left side of the holes which are not plugged on the right side is plugged, the right side of the holes which are not plugged on the left side is plugged, and the effect of plugging the holes on the cross sections of the left side and the right side at intervals is achieved.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by the present specification, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims

1. A dislocation formula carborundum honeycomb ceramic carrier cross-section plugging device, including:

a working machine bed plate (1);

the upper part of the supporting foot stand (2) is welded with the working machine bed plate (1);

the installation top frame (3), the lower part of the installation top frame (3) is welded with the working machine bed plate (1);

it is characterized by also comprising:

the operation control screen (4), the operation control screen (4) is connected with the mounting top frame (3);

the lower part of the standing solidification transfer system (5) is connected with a working machine bed plate (1);

the lower part of the dislocation unidirectional plugging system (6) is connected with the working machine bed plate (1);

the fixed-length extrusion system (7) in the hole is connected with the mounting top frame (3) above the fixed-length extrusion system (7) in the hole;

the standing coagulation transfer system (5) comprises:

the lower part of the motor frame (501) is connected with a working machine bed plate (1) through bolts;

the power motor (502), the power motor (502) is connected with the motor frame (501) through bolts;

the axis of the first transmission wheel (503) is fixedly connected with the output shaft of the power motor (502);

the axle center of the first rotating shaft rod (504) is fixedly connected with the first driving wheel (503);

the axle center of the second driving wheel (505) is fixedly connected with the first rotating shaft rod (504);

the first bearing frame plate (506), the first bearing frame plate (506) is rotationally connected with the first rotating shaft rod (504), and the lower part of the first bearing frame plate (506) is welded with the motor frame (501);

the outer ring surface of the third driving wheel (507) is in transmission connection with the first driving wheel (503) through a belt, and the third driving wheel (507) is in rotary connection with the first bearing frame plate (506);

the axle center of the first half gear (508) is fixedly connected with a third driving wheel (507);

a first spur gear (509), the first spur gear (509) meshing with the first half gear (508);

the shaft center of the first torsion spring rotating shaft seat (5010) is fixedly connected with the first flat gear (509);

the first fixed shaft column (5011), the first fixed shaft column (5011) is rotatably connected with the first torsion spring rotating shaft base (5010), and the lower part of the first fixed shaft column (5011) is fixedly connected with the working machine bedplate (1);

the first transfer deflector rod (5012), the first transfer deflector rod (5012) is fixedly connected with the first torsion spring rotating shaft seat (5010);

a fourth transmission wheel (5013);

the second rotating shaft rod (5014), the second rotating shaft rod (5014) is fixedly connected with the fourth transmission wheel (5013);

the second bearing frame plate (5015), the second bearing frame plate (5015) is in rotating connection with the second rotating shaft rod (5014), and the lower part of the second bearing frame plate (5015) is welded with the motor frame (501);

the fifth transmission wheel (5016), the axle center of the fifth transmission wheel (5016) is fixedly connected with the second rotating shaft rod (5014);

the outer ring surface of the sixth transmission wheel (5017) is in transmission connection with the fifth transmission wheel (5016) through a belt, and the axle center of the sixth transmission wheel (5017) is in rotary connection with the second bearing frame plate (5015);

the axle center of the second half gear (5018) is fixedly connected with the sixth transmission wheel (5017);

a second spur gear (5019), the second spur gear (5019) meshing with the second half gear (5018);

the axis of the second torsion spring rotating shaft seat (5020) is fixedly connected with a second flat gear (5019);

a second fixed shaft column (5021), wherein the second fixed shaft column (5021) is rotatably connected with a second torsion spring rotating shaft seat (5020), and the lower part of the second fixed shaft column (5021) is fixedly connected with a working machine bedplate (1);

the second transfer deflector rod (5022), the second transfer deflector rod (5022) is fixedly connected with the second torsion spring rotating shaft seat (5020);

the lower part of the electric transmission mechanism (5023) is connected with the working machine bed plate (1);

the lower part of the bearing transfer long plate (5024) is fixedly connected with the working machine bed plate (1);

the anti-sticking bearing transfer cloth (5025), wherein the anti-sticking bearing transfer cloth (5025) is contacted with the bearing transfer long plate (5024);

the winding control roller (5026), anti-sticking bearing transfer cloth (5025) is wound on the outer surface of the winding control roller (5026), and the winding control roller (5026) is in rotating connection with the working machine bed plate (1);

the output shaft of the control motor (5027) is fixedly connected with the winding control roller (5026), and the lower part of the control motor (5027) is connected with the working machine bed plate (1) through a bolt;

the outer ring surface of the seventh transmission wheel (5028) is in transmission connection with a fourth transmission wheel (5013) through a belt, and the axis of the seventh transmission wheel (5028) is in rotational connection with a second bearing frame plate (5015);

the axis of the fourth flat gear (5029) is fixedly connected with a seventh transmission wheel (5028);

a fifth spur gear (5030), the fifth spur gear (5030) meshing with the fourth spur gear (5029);

the axle center of the eighth driving wheel (5031) is fixedly connected with the fifth flat gear (5030), the axle center of the eighth driving wheel (5031) is rotatably connected with the second bearing frame plate (5015), and the outer annular surface of the eighth driving wheel (5031) is in transmission connection with the second driving wheel (505) through a belt;

a transfer table (5032), wherein the lower part of the transfer table (5032) is welded with the working machine bed plate (1);

the dislocation unidirectional plugging system (6) comprises:

the lower part of the first mounting bearing frame (601) is welded with the working machine bed plate (1);

the lower part of the first pug extruder (602) is connected with a first mounting bearing frame (601) through bolts;

the first extrusion cylinder (603), the first extrusion cylinder (603) is connected with the first pug extruder (602);

the first extrusion inner inserting positioning pipe (604), the first extrusion inner inserting positioning pipe (604) is connected with the first extrusion barrel (603);

the lower part of the first electric rotating shaft frame seat (605) is connected with a working machine bed plate (1) through bolts;

a first engaging seat (606), the first engaging seat (606) being connected to the first electric spindle frame (605);

a first opening and closing electric control shaft seat (607), wherein the lower part of the first opening and closing electric control shaft seat (607) is connected with a first connecting seat platform (606) through a bolt;

the first semicircular clamping ring (608), the first semicircular clamping ring (608) is connected with the first opening and closing electric control shaft seat (607);

the second semicircular clamping ring (609), the second semicircular clamping ring (609) is connected with the first opening and closing electric control shaft seat (607);

a second mounting bearing frame (6010), wherein the lower part of the second mounting bearing frame (6010) is welded with the working machine bed plate (1);

a second pug extruder (6011), wherein the lower part of the second pug extruder (6011) is in bolted connection with a second mounting bearing frame (6010);

the second extrusion cylinder (6012), the second extrusion cylinder (6012) is connected with the second pug extruder (6011);

a second extrusion inner inserting positioning pipe (6013), wherein the second extrusion inner inserting positioning pipe (6013) is connected with a second extrusion barrel (6012);

a second electric rotating shaft frame seat (6014), wherein the lower part of the second electric rotating shaft frame seat (6014) is in bolt connection with the working machine bed plate (1);

a second connecting seat stand (6015), wherein the lower part of the second connecting seat stand (6015) is connected with a second electric rotating shaft frame stand (6014);

a second opening and closing electric control shaft seat (6016), wherein the lower part of the second opening and closing electric control shaft seat (6016) is in bolt connection with a second connecting seat platform (6015);

a third semicircular clamping ring (6017), wherein the third semicircular clamping ring (6017) is connected with a second opening and closing electric control shaft seat (6016);

a fourth semicircular clamping ring (6018), wherein the fourth semicircular clamping ring (6018) is connected with a second opening and closing electric control shaft seat (6016);

the fixed-length extrusion system (7) in the hole comprises:

the upper part of the first electric lifting column (701) is connected with the mounting top frame (3) through a bolt;

the upper part of the second electric lifting column (702) is connected with the mounting top frame (3) through a bolt;

the upper part of the long mounting plate (703) is sequentially connected with a first electric lifting column (701) and a second electric lifting column (702) through bolts;

the upper part of the electric sliding rail (704) is connected with the mounting long plate (703) through a bolt;

the electric sliding seat (705), the electric sliding seat (705) is connected with the electric sliding rail (704) in a sliding way;

the damping rotating shaft seat (706), the damping rotating shaft seat (706) is fixedly connected with the electric sliding seat (705);

the connecting shaft column (707) is rotationally connected with the damping rotating shaft seat (706);

the axis of the third gear (708) is fixedly connected with the connecting shaft column (707);

a fixed lantern ring (709), wherein the upper part of the fixed lantern ring (709) is fixedly connected with the connecting shaft column (707);

the reverse positioning insertion rod group (7010), the reverse positioning insertion rod group (7010) is sleeved with the fixed lantern ring (709);

after the silicon carbide honeycomb ceramic carrier is fixed, the straight pipes of the first extrusion interpolation positioning pipe (604) and the straight pipes of the second extrusion interpolation positioning pipe (6013) are aligned with the holes of the silicon carbide honeycomb ceramic carrier, and the straight pipes of the first extrusion interpolation positioning pipe (604) and the straight pipes of the second extrusion interpolation positioning pipe (6013) are alternately arranged in the front-rear direction.

2. The dislocation type silicon carbide honeycomb ceramic carrier section plugging device according to claim 1, wherein two coiling control rollers (5026) and two control motors (5027) are arranged.

3. The dislocation type silicon carbide honeycomb ceramic carrier section plugging device according to claim 2, wherein the toothed part at the front end of the incomplete rack rail plate (7011) can drive the third flat gear (708) to rotate one hundred eighty degrees.