CN113370376B - Silicate fiberboard manufacturing device for homogenizing powder distribution - Google Patents

Abstract

The invention relates to the field of silicate, in particular to a silicate fiber board manufacturing device for homogenizing powder distribution. The technical problems of the invention are as follows: a silicate fiber board manufacturing device for homogenizing powder distribution is provided. The technical implementation scheme of the invention is as follows: a silicate fiber board manufacturing device for homogenizing powder distribution comprises a mixing system, a transferring system and the like; the mixing system is connected with the transfer system. The method abandons the manufacturing flow of the traditional silicate fiber board, reduces holes and looseness of the fiber board in the manufacturing process, improves the service strength of the fiber board, improves the surface evenness of the fiber board by using a mode of paving a fiber thin layer on a board manufacturing die, and simultaneously improves the wrapping property of the outermost layer of the fiber board, avoids the damage of the fiber board in a humid environment and avoids the infiltration of moisture.

Description

Silicate fiberboard manufacturing device for homogenizing powder distribution

Technical Field

The invention relates to the field of silicate, in particular to a silicate fiber board manufacturing device for homogenizing powder distribution.

Background

Most of silicate has high melting point and stable chemical property, and is a main raw material in silicate industry; silicate products and materials are widely used in various industries, scientific research and daily life.

In the prior art, in the manufacturing process of the silicate type fiber board, fiber powder and silicate seed crystals are directly mixed and then pressed at high temperature, and when the method has the problem, the fiber board has a plurality of holes and looseness in the fiber board due to the fact that the silicate seed crystals and the fiber powder are not tightly combined in the manufacturing process, so that the strength of the fiber board is greatly reduced; meanwhile, the traditional plate making mode enables the outer surface of the fiber board to be rough, and the attractiveness of the fiber board is affected.

In order to solve the problems of strength and aesthetic property of the fiber board, a silicate fiber board manufacturing device for homogenizing powder distribution is urgently needed.

Disclosure of Invention

In order to overcome the problems that in the prior art, in the manufacturing process of a fiber plate of silicate, fiber powder and silicate seed crystals are directly mixed and then pressed at high temperature, the fiber plate has a great number of holes and looseness in the fiber plate due to insufficient combination of the silicate seed crystals and the fiber powder in the manufacturing process, so that the strength of the fiber plate is greatly reduced; meanwhile, the traditional plate making mode has the defects that the outer surface of the fiber board is rough and the attractiveness of the fiber board is affected, and the technical problem of the invention is that: a silicate fiber board manufacturing device for homogenizing powder distribution is provided.

The technical implementation scheme of the invention is as follows: a silicate fiberboard manufacturing device for homogenizing powder distribution comprises a bottom column, a bottom plate, a controller, a bearing system, a portal frame, a mixing system, a transferring system, an extruding system, a powder spraying system and a discharging system; the bottom column is fixedly connected with the bottom plate; the bottom plate is connected with the bearing system; the bottom plate is fixedly connected with the portal frame; the bottom plate is connected with the transfer system; the bottom plate is connected with the extrusion system; the bottom plate is sequentially connected with the powder spraying system and the discharging system; the controller is connected with the portal frame; the bearing system is connected with the transfer system; the portal frame is connected with the mixing system; the portal frame is connected with the transfer system; the mixing system is connected with the transfer system.

More preferably, the bearing system comprises a first supporting frame, a fixed plate, a first electric sliding rail, a sliding block, a carrying box and a first flat gear; the first support frame is connected with the transfer system; the first support frame is fixedly connected with the fixed plate; the first support frame is fixedly connected with the bottom plate; the fixed plate is connected with the first electric sliding rail through bolts; the first electric sliding rail is in sliding connection with the sliding block; the first support frame, the fixed plate, the first electric sliding rail and the sliding block are symmetrically provided with two groups; the sliding block is rotationally connected with the carrying box; the carrying box is fixedly connected with the first flat gear.

More preferably, the mixing system comprises a first bevel gear, a first rotating shaft, a first driving wheel, a second driving wheel, a first connecting shaft, a first sleeve shaft, a first supporting plate, a first electric push rod and a stirrer; the first bevel gear is fixedly connected with the first rotating shaft; the first bevel gear is connected with the transfer system; the first rotating shaft is fixedly connected with the first driving wheel; the first rotating shaft is rotationally connected with the portal frame through a bracket; the outer ring surface of the first driving wheel is in driving connection with the second driving wheel through a belt; the second driving wheel is fixedly connected with the first connecting shaft; the first connecting shaft is connected with the first sleeve shaft; the first connecting shaft is rotationally connected with the portal frame; the first sleeve shaft is rotationally connected with the first supporting plate; the first sleeve shaft is fixedly connected with the stirrer; the first supporting plate is fixedly connected with the first electric push rod; the first electric push rod is connected with the portal frame through bolts.

More preferably, the transfer system comprises a power motor, an output shaft, a worm, a second bevel gear, a third driving wheel, a fourth driving wheel, a second connecting shaft, a second sleeve shaft, a second flat gear, a second supporting plate, a second electric push rod, a third bevel gear, a worm wheel, a third connecting shaft, a third sleeve shaft, a fourth bevel gear, a third supporting plate, a third electric push rod, a fifth bevel gear, a first screw rod, a limiting rod, a transport case and an electric valve; the power motor is fixedly connected with the output shaft; the power motor is connected with the bottom plate through bolts; the output shaft is fixedly connected with the worm, the second bevel gear and the third driving wheel in sequence; the output shaft is rotationally connected with the bottom plate through a bracket; the worm is meshed with the worm wheel; the outer ring surface of the third driving wheel is in driving connection with the fourth driving wheel through a belt; the second connecting shaft is fixedly connected with the fourth driving wheel and the third bevel gear in sequence; the second connecting shaft is connected with the second sleeve shaft; the second connecting shaft is rotationally connected with the portal frame; the second sleeve shaft is fixedly connected with a second flat gear; the second sleeve shaft is rotationally connected with the second supporting plate; the second supporting plate is fixedly connected with the second electric push rod; the second electric push rod is connected with the first support frame through bolts; the third bevel gear is meshed with the first bevel gear; the worm wheel is fixedly connected with the third connecting shaft; the third connecting shaft is connected with a third sleeve shaft; the third connecting shaft is rotationally connected with the bottom plate; the third sleeve shaft is fixedly connected with a fourth bevel gear; the third sleeve shaft is rotationally connected with the third supporting plate; the third supporting plate is fixedly connected with a third electric push rod; the third electric push rod is connected with the bottom plate through a bracket through a bolt; a fifth bevel gear is arranged above the fourth bevel gear; the fifth bevel gear is fixedly connected with the first screw rod; the first screw rod is connected with the transport case in a screwing way; the first screw rod is rotationally connected with the bottom plate through a bracket; the limiting rod is in sliding connection with the transport case; the limiting rod is fixedly connected with the bottom plate through a bracket; an electric valve is arranged in the transport case.

More preferably, the extrusion system comprises a plate making die, a heating block, a top block, a fourth electric push rod, a second supporting frame, a hydraulic rod and an extrusion plate; the outer surface of the plate-making die is provided with a heating block; the plate making die is in sliding connection with the top block; the plate making die is fixedly connected with the bottom plate; the top block is fixedly connected with the fourth electric push rod; the fourth electric push rod is connected with the bottom plate through a bolt; the top block and the fourth electric push rod are provided with two groups; the side surface of the fourth electric push rod is provided with a second supporting frame; the second support frame is connected with the hydraulic rod through bolts; the second support frame is fixedly connected with the bottom plate; the hydraulic rod is fixedly connected with the extrusion plate; the hydraulic rod is provided with two groups.

More preferably, the powder spraying system is provided with a third support frame, a storage box, a first material conveying pipe, a fan, a second material conveying pipe, a powder sprayer and a second electric sliding rail; the third support frame is fixedly connected with the storage box; the third support frame is connected with the fan through bolts; the third support frame is fixedly connected with the second electric sliding rail; the third support frame is fixedly connected with the bottom plate; the storage box is connected with the first conveying pipe through bolts; the first conveying pipe is connected with the fan through bolts; the fan is connected with the second conveying pipe through bolts; the second material conveying pipe is fixedly connected with the powder sprayer; the powder sprayer is in sliding connection with the second electric sliding rail.

More preferably, the discharging system comprises a sixth bevel gear, a fourth supporting plate, a fifth electric push rod, a telescopic shaft, a seventh bevel gear, an eighth bevel gear, a second screw rod, a fifth driving wheel, a first carrying plate, a first straight sliding rail, a sixth driving wheel, a third screw rod, a second carrying plate and a second straight sliding rail; the sixth bevel gear is fixedly connected with the telescopic shaft; the fourth supporting plate is rotationally connected with the telescopic shaft; the fourth supporting plate is fixedly connected with the fifth electric push rod; the fifth electric push rod is connected with the bottom plate through a bolt; the telescopic shaft is fixedly connected with a seventh bevel gear; the telescopic shaft is rotationally connected with the bottom plate; the seventh bevel gear is meshed with the eighth bevel gear; the second screw rod is fixedly connected with an eighth bevel gear and a fifth driving wheel in sequence; the second screw rod is screwed with the first carrying plate; the second screw rod is rotationally connected with the first straight sliding rail; the outer ring surface of the fifth driving wheel is in driving connection with the sixth driving wheel through a belt; the first carrying plate is in sliding connection with the first straight sliding rail; the first straight sliding rail is fixedly connected with the bottom plate; the sixth driving wheel is fixedly connected with the third screw rod; the third screw rod is screwed with the second carrying plate; the second carrying plate is in sliding connection with the second straight slide rail; the second straight slide rail is fixedly connected with the bottom plate.

More preferably, the bottom surface of the stirrer is provided with a staggered poking plate, and the outer ring surface of the connecting rod is provided with a stirring rod.

More preferably, the telescopic shaft is composed of two connecting rods, the outer ring surface of the connecting rod close to the seventh bevel gear is provided with a convex strip which can slide relatively with the connecting rod close to the sixth bevel gear, and meanwhile, the outer ring surface of the connecting rod close to the sixth bevel gear is also provided with a convex strip.

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

the invention passes through a bearing system, a mixing system, a transferring system, an extruding system, a powder spraying system and a discharging system; mixing silicate fiber board powder, stirring the mixed powder continuously, pressurizing the mixed powder at high temperature, realizing high combination of silicate seed crystal and fiber powder while pressing, reducing holes and looseness in the fiber board, and demolding the prepared fiber board.

And secondly, the method abandons the manufacturing flow of the traditional silicate fiber board, reduces holes and looseness of the fiber board in the manufacturing process, improves the service strength of the fiber board, improves the surface flatness of the fiber board by using a mode of paving a fiber thin layer on a board manufacturing die, improves the wrapping property of the outermost layer of the fiber board, avoids the damage of the fiber board in a humid environment, and avoids the infiltration of moisture.

Drawings

FIG. 1 is a schematic perspective view of a first embodiment of the present invention;

FIG. 2 is a schematic view of a second perspective structure of the present invention;

FIG. 3 is a schematic view of a third perspective structure of the present invention;

FIG. 4 is a schematic perspective view of a carrying system according to the present invention;

FIG. 5 is a schematic perspective view of a hybrid system according to the present invention;

FIG. 6 is a schematic view showing a first perspective structure of the agitator of the present invention;

FIG. 7 is a schematic view showing a second perspective structure of the agitator of the present invention;

FIG. 8 is a schematic view of a first perspective of the transfer system of the present invention;

FIG. 9 is a schematic diagram of a second perspective view of the transfer system of the present invention;

FIG. 10 is a schematic view of a portion of a transport system according to the present invention;

FIG. 11 is a schematic perspective view of an extrusion system of the present invention;

FIG. 12 is a schematic view of a first perspective structure of the powder injection system of the present invention;

FIG. 13 is a schematic view of a second perspective structure of the powder injection system of the present invention;

FIG. 14 is a schematic view of a first perspective of the discharge system of the present invention;

fig. 15 is a schematic view showing a second perspective structure of the discharging system of the present invention.

The marks of the components in the drawings are as follows: 1. a bottom post, 2, a bottom plate, 3, a controller, 4, a carrying system, 5, a portal frame, 6, a mixing system, 7, a transfer system, 8, an extrusion system, 9, a powder injection system, 10, a discharging system, 401, a first support frame, 402, a fixed plate, 403, a first electric slide rail, 404, a slider, 405, a carrying case, 406, a first flat gear, 601, a first bevel gear, 602, a first rotating shaft, 603, a first driving wheel, 604, a second driving wheel, 605, a first connecting shaft, 606, a first sleeve shaft, 607, a first supporting plate, 608, a first electric push rod, 609, a stirrer, 701, a power motor, 702, an output shaft, 703, a worm, 704, a second bevel gear, 705, a third driving wheel, 706, a fourth driving wheel, 707, a second connecting shaft, 708, a second sleeve shaft, 709, a second flat gear, 7010, a second supporting plate, 7011, a second electric push rod, 7012, a third bevel gear, 7013, worm gears, 7014, a third connecting shaft, 7015, a third sleeve shaft, 7016, a fourth bevel gear, 7017, a third supporting plate, 7018, a third electric push rod, 7019, a fifth bevel gear, 7020, a first screw rod, 7021, a limit rod, 7022, a transport box, 7023, an electric valve, 801, a plate forming die, 802, a heating block, 803, a top block, 804, a fourth electric push rod, 805, a second supporting frame, 806, a hydraulic rod, 807, a pressing plate, 901, a third supporting frame, 902, a storage box, 903, a first conveying pipe, 904, a fan, 905, a second conveying pipe, 906, a powder sprayer, 907, a second electric slide rail, 1001, a sixth bevel gear, 1002, a fourth supporting plate, 1003, a fifth electric push rod, 1004, a telescopic shaft, 1005, a seventh bevel gear, 1006, an eighth bevel gear, 1007, a second screw rod, 1008, a fifth driving wheel, 1009, a first carrying plate, 10010, a first straight slide rail, 10011. sixth drive wheel, 10012, third lead screw, 10013, second year thing board, 10014, second straight slide rail.

Detailed Description

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

Example 1

The silicate fiber board manufacturing device for homogenizing powder distribution comprises a bottom column 1, a bottom plate 2, a controller 3, a bearing system 4, a portal frame 5, a mixing system 6, a transferring system 7, an extruding system 8, a powder spraying system 9 and a discharging system 10, wherein the bottom plate is provided with a plurality of grooves; the bottom column 1 is fixedly connected with the bottom plate 2; the bottom plate 2 is connected with the bearing system 4; the bottom plate 2 is fixedly connected with the portal frame 5; the bottom plate 2 is connected with a transfer system 7; the bottom plate 2 is connected with the extrusion system 8; the bottom plate 2 is sequentially connected with a powder spraying system 9 and a discharging system 10; the controller 3 is connected with the portal frame 5; the bearing system 4 is connected with the transfer system 7; the portal frame 5 is connected with the mixing system 6; the portal frame 5 is connected with the transfer system 7; the mixing system 6 is connected to a transport system 7.

Before the device operates, the bottom post 1 is installed and fixed at a stable working place, so that the bottom plate 2 is in a flat state, a power supply is externally connected, a controller 3 is manually operated by a worker to start the device, the operation transmission condition among all systems is checked, and the device is closed after the fact that all systems do not have operation problems is confirmed; the device is externally connected with a silicate seed crystal powder and fiber powder conveying device, the device is started by manually operating the controller 3 again, the carrying system 4 carries out carrying on the mixed powder, meanwhile, the powder is positioned to the mixing system 6, then the mixing system 6 on the portal frame 5 starts to operate, the mixed powder is continuously stirred, and rapid dislocation among the powder is realized by using stirring plates which are arranged on the stirrer 609 in a staggered manner, so that uniform mixing is completed; in the stirring process, the powder spraying system 9 operates, and the fiber powder thin layer is paved on the plate making mold 801; then the transfer system 7 drives the carrying box 405 to rotate so as to realize the bearing of the mixed powder, and meanwhile, the mixed powder is fed on the plate making die 801; then the extrusion system 8 operates to pressurize the mixed powder at high temperature, high combination of silicate seed crystals and fiber powder is realized while pressing, holes and looseness in the fiber plate are reduced, finally, the manufactured fiber plate is demolded, then the unloading system 10 operates to accept the fiber plate, and the fiber plate is moved out of the powder spraying system 9, so that subsequent uniform collection is realized; the method abandons the manufacturing flow of the traditional silicate fiber board, reduces holes and looseness of the fiber board in the manufacturing process, improves the service strength of the fiber board, improves the surface flatness of the fiber board by adopting a mode of paving a fiber thin layer on the board manufacturing mold 801, improves the wrapping property of the outermost layer of the fiber board, avoids the damage of the fiber board in a humid environment, and avoids the infiltration of moisture.

The bearing system 4 comprises a first supporting frame 401, a fixed plate 402, a first electric sliding rail 403, a sliding block 404, a carrying box 405 and a first flat gear 406; the first support 401 is connected with the transfer system 7; the first support 401 is fixedly connected with the fixed plate 402; the first support 401 is fixedly connected with the bottom plate 2; the fixed plate 402 is in bolt connection with the first electric slide rail 403; the first electric slide rail 403 is slidably connected with the slider 404; two groups of the first support frame 401, the fixed plate 402, the first electric slide rail 403 and the slide block 404 are symmetrically arranged; the sliding block 404 is rotationally connected with the carrying box 405; the carrying case 405 is fixedly connected with the first flat gear 406.

The external silicate seed crystal powder and fiber powder conveying device simultaneously conveys powder to a carrying box 405, then a first electric slide rail 403 on a fixed plate 402 supported by a first support frame 401 runs, two groups of first electric slide rails 403 run simultaneously and respectively drive corresponding slide blocks 404 to move, the two groups of slide blocks 404 jointly drive the carrying box 405 to be positioned to a mixing system 6, and after mixing and stirring are completed, a first flat gear 406 obtains power from a transfer system 7 to drive the carrying box 405 to rotate so as to realize that mixed powder is conveyed to the transfer system 7 in a dumping manner; the system receives the mixed powder and simultaneously positions the powder to a subsequent operating system.

The mixing system 6 comprises a first bevel gear 601, a first rotating shaft 602, a first driving wheel 603, a second driving wheel 604, a first connecting shaft 605, a first sleeve shaft 606, a first supporting plate 607, a first electric push rod 608 and a stirrer 609; the first bevel gear 601 is fixedly connected with the first rotating shaft 602; the first bevel gear 601 is connected with the transfer system 7; the first rotating shaft 602 is fixedly connected with a first driving wheel 603; the first rotating shaft 602 is rotatably connected with the portal frame 5 through a bracket; the outer ring surface of the first driving wheel 603 is in driving connection with the second driving wheel 604 through a belt; the second driving wheel 604 is fixedly connected with a first connecting shaft 605; the first connecting shaft 605 is connected with the first sleeve shaft 606; the first connecting shaft 605 is rotatably connected with the portal frame 5; the first sleeve 606 is rotatably connected with the first support plate 607; the first sleeve 606 is fixedly connected with the stirrer 609; the first supporting plate 607 is fixedly connected with the first electric push rod 608; the first electric putter 608 is bolted to the gantry 5.

When the carrying case 405 is positioned right below the stirrer 609, the first electric push rod 608 operates to drive the first supporting plate 607 to move, the first sleeve shaft 606 drives the stirrer 609 to extend into the carrying case 405 in the following movement process, and the third bevel gear 7012 is in a rotating state due to the operation of the power motor 701 in the transfer system 7, so that the first bevel gear 601 obtains power from the third bevel gear 7012 to drive the first rotating shaft 602 to rotate, the first rotating shaft 602 drives the first driving wheel 603 to drive the second driving wheel 604, the second driving wheel 604 drives the first connecting shaft 605 to drive the first sleeve shaft 606, the first sleeve shaft 606 drives the stirrer 609 to continuously rotate, and due to the arrangement of the stirring plate and the stirring rod on the stirrer 609, the mixed powder is continuously stirred in a staggered mode, so that silicate seed powder and fiber powder are mixed more quickly.

The transfer system 7 comprises a power motor 701, an output shaft 702, a worm 703, a second bevel gear 704, a third driving wheel 705, a fourth driving wheel 706, a second connecting shaft 707, a second sleeve shaft 708, a second flat gear 709, a second support plate 7010, a second electric push rod 7011, a third bevel gear 7012, a worm wheel 7013, a third connecting shaft 7014, a third sleeve shaft 7015, a fourth bevel gear 7016, a third support plate 7017, a third electric push rod 7018, a fifth bevel gear 7019, a first lead screw 7020, a limiting rod 7021, a transport case 7022 and an electric valve 7023; the power motor 701 is fixedly connected with the output shaft 702; the power motor 701 is connected with the bottom plate 2 through bolts; the output shaft 702 is fixedly connected with a worm 703, a second bevel gear 704 and a third driving wheel 705 in sequence; the output shaft 702 is rotatably connected with the bottom plate 2 through a bracket; the worm 703 is meshed with the worm wheel 7013; the outer ring surface of the third transmission wheel 705 is in transmission connection with a fourth transmission wheel 706 through a belt; the second connecting shaft 707 is fixedly connected with the fourth driving wheel 706 and the third bevel gear 7012 in sequence; the second connecting shaft 707 is connected to a second sleeve shaft 708; the second connecting shaft 707 is rotatably connected to the gantry 5; the second sleeve shaft 708 is fixedly connected with a second flat gear 709; the second sleeve shaft 708 is rotatably connected to the second support plate 7010; the second support plate 7010 is fixedly connected with the second electric push rod 7011; the second electric push rod 7011 is in bolt connection with the first support frame 401; third bevel gear 7012 is in mesh with first bevel gear 601; the worm gear 7013 is fixedly connected with the third connecting shaft 7014; the third connecting shaft 7014 is connected to a third sleeve shaft 7015; the third connecting shaft 7014 is rotatably connected with the bottom plate 2; the third sleeve shaft 7015 is fixedly connected with a fourth bevel gear 7016; the third sleeve 7015 is rotatably connected with the third support plate 7017; the third support plate 7017 is fixedly connected with the third electric push rod 7018; the third electric push rod 7018 is connected with the bottom plate 2 through a bracket through a bolt; a fifth bevel gear 7019 is arranged above the fourth bevel gear 7016; the fifth bevel gear 7019 is fixedly connected with the first screw rod 7020; the first screw rod 7020 is screwed with the transport case 7022; the first screw rod 7020 is rotatably connected with the bottom plate 2 through a bracket; the limiting rod 7021 is in sliding connection with the transport case 7022; the limiting rod 7021 is fixedly connected with the bottom plate 2 through a bracket; an electrically operated valve 7023 is provided inside the transport box 7022.

After the mixing and stirring are completed, the second electric push rod 7011 operates to drive the second support plate 7010 to move, the second sleeve shaft 708 drives the second flat gear 709 to engage with the first flat gear 406 in the following movement process, the output shaft 702 drives the worm 703, the second bevel gear 704 and the third driving wheel 705 to rotate due to the operation of the power motor 701, the third driving wheel 705 drives the fourth driving wheel 706 to drive the second connecting shaft 707 to rotate, the second connecting shaft 707 drives the second sleeve shaft 708 and the third bevel gear 7012 to rotate, and the third bevel gear 7012 drives the mixing system 6 to realize power transmission between the systems; however, the second sleeve shaft 708 drives the second flat gear 709 to drive the first flat gear 406, the first flat gear 406 drives the carrying case 405 to start to rotate slowly, so as to realize dumping of mixed powder in the carrying case 405, meanwhile, the mixed powder is supported by the transporting case 7022, then the second electric push rod 7011 returns, meanwhile, the third electric push rod 7018 operates to drive the third supporting plate 7017 to move, one end of the third connecting shaft 7014 is set to be a hexagonal rod, so that the third sleeve shaft 7015 drives the fourth bevel gear 7016 to mesh with the fifth bevel gear 7019 in the following movement process, the worm 703 drives the worm gear 7013 to drive the third connecting shaft 7014 to rotate, the third connecting shaft 7014 drives the third sleeve shaft 7015 to rotate to drive the fourth bevel gear 7016, the fourth bevel gear 7016 drives the first lead screw 7020 to rotate, the first lead screw 7020 rotates to drive the transporting case 7022 to slide on the limiting rod 7021, and when a powder outlet at the bottom of the transporting case 7022 is above the plate 801, the electric valve 7023 inside the transporting case 7022 is opened, so that powder is discharged from the inner part of the transporting case 7022 in the following movement process of the plate 7022, and the powder is simultaneously realized in the moving process of the transporting case 7022.

The extrusion system 8 comprises a plate making die 801, a heating block 802, a top block 803, a fourth electric push rod 804, a second supporting frame 805, a hydraulic rod 806 and an extrusion plate 807; the outer surface of the plate making die 801 is provided with a heating block 802; the plate making die 801 is in sliding connection with the top block 803; the plate making die 801 is fixedly connected with the bottom plate 2; the top block 803 is fixedly connected with a fourth electric push rod 804; the fourth electric push rod 804 is connected with the bottom plate 2 through a bolt; two groups of top blocks 803 and fourth electric push rods 804 are arranged; a second supporting frame 805 is arranged on the side surface of the fourth electric push rod 804; the second support 805 is bolted to the hydraulic bar 806; the second supporting frame 805 is fixedly connected with the bottom plate 2; the hydraulic rod 806 is fixedly connected with the extrusion plate 807; the hydraulic rods 806 are provided in two groups.

After the powder is fed into the plate making mold 801, the heating block 802 is heated and keeps the plate making mold 801 at a constant temperature, the two sets of hydraulic rods 806 on the second supporting frame 805 simultaneously operate to drive the extruding plate 807 to start moving downwards, the extruding plate 807 extrudes the heated powder on the plate making mold 801 to be matched with the binder to be added to form the silicate fiber board, after a period of pressure maintaining, the two sets of hydraulic rods 806 return, and then the two sets of fourth electric push rods 804 operate to respectively drive the respective corresponding top blocks 803 to move, so that the fiber board is separated from the plate making mold 801 and is in a suspended state, and the unloading system 10 is matched to complete unloading.

The powder spraying system 9 is provided with a third support 901, a storage box 902, a first material conveying pipe 903, a fan 904, a second material conveying pipe 905, a powder sprayer 906 and a second electric sliding rail 907; the third support 901 is fixedly connected with the storage box 902; the third support 901 is connected with a fan 904 through bolts; the third support 901 is fixedly connected with a second electric slide rail 907; the third support 901 is fixedly connected with the bottom plate 2; the storage tank 902 is bolted to the first feed delivery conduit 903; the first material conveying pipe 903 is connected with a fan 904 through bolts; the fan 904 is in bolted connection with a second feed conveyor pipe 905; the second feed conveyor pipe 905 is fixedly connected with the powder sprayer 906; the spreader 906 is slidably connected to a second motorized slide rail 907.

Before the transfer system 7 carries out the material loading of mixed powder, fan 904 operates the inside fibre powder of bin 902 on the first support frame 901 of drawing motion first, and the powder passes through first conveying pipeline 903 and flows through second conveying pipeline 905 and reach the powder spreader 906 inside, and then the valve on the powder spreader 906 opens, and the operation of second electronic slide rail 907 drives the powder spreader 906 and begins lateral shifting simultaneously, and the mode that the powder spreader 906 is with the powder spraying realizes forming one deck fibre powder thin layer on the board mould 801 simultaneously, is favorable to realizing the drawing of patterns of fibreboard in the suppression process, realizes the leveling of fibreboard surface simultaneously.

The unloading system 10 comprises a sixth bevel gear 1001, a fourth supporting plate 1002, a fifth electric push rod 1003, a telescopic shaft 1004, a seventh bevel gear 1005, an eighth bevel gear 1006, a second screw 1007, a fifth driving wheel 1008, a first carrying plate 1009, a first straight sliding rail 10010, a sixth driving wheel 10011, a third screw 10012, a second carrying plate 10013 and a second straight sliding rail 10014; the sixth bevel gear 1001 is fixedly connected with the telescopic shaft 1004; the fourth support plate 1002 is rotatably connected with the telescopic shaft 1004; the fourth supporting plate 1002 is fixedly connected with the fifth electric push rod 1003; the fifth electric push rod 1003 is connected with the bottom plate 2 through a bolt; the telescopic shaft 1004 is fixedly connected with a seventh bevel gear 1005; the telescopic shaft 1004 is rotatably connected with the bottom plate 2; the seventh bevel gear 1005 is meshed with the eighth bevel gear 1006; the second screw 1007 is fixedly connected with the eighth bevel gear 1006 and the fifth driving wheel 1008 in sequence; the second screw 1007 is screwed with the first loading plate 1009; the second screw 1007 is rotatably connected with the first straight slide rail 10010; the outer ring surface of the fifth transmission wheel 1008 is in transmission connection with the sixth transmission wheel 10011 through a belt; the first loading plate 1009 is slidably connected to the first straight sliding rail 10010; the first straight slide 10010 is fixedly connected with the bottom plate 2; the sixth driving wheel 10011 is fixedly connected with a third screw rod 10012; the third screw rod 10012 is screwed with the second carrying plate 10013; the second carrier plate 10013 is slidably connected to the second straight slide 10014; the second straight slide 10014 is fixedly coupled to the floor 2.

When the fiberboard is separated from the fiberboard making die 801 and is in a suspended state, the fifth electric push rod 1003 operates to drive the fourth supporting plate 1002 to move, the fourth supporting plate 1002 drives the connecting rod at one side of the telescopic shaft 1004 to move in the moving process, so that the sixth bevel gear 1001 engages the second bevel gear 704 in the following moving process, the sixth bevel gear 1001 obtains power from the second bevel gear 704 to drive the telescopic shaft 1004 to rotate, the telescopic shaft 1004 drives the seventh bevel gear 1005 to drive the eighth bevel gear 1006, the eighth bevel gear 1006 drives the second lead screw 1007 to drive the fifth driving wheel 1008, and meanwhile, the second lead screw 1007 drives the first carrying plate 1009 to slide on the first straight sliding rail 10010, so that the first carrying plate 1009 enters the suspended lower space of the fiberboard, and the same way that the fifth driving wheel 1008 drives the sixth driving wheel 10011 to drive the third lead screw 10012 to rotate, and the third lead screw 10012 drives the second carrying plate 10013 to slide on the second straight sliding rail 10014, so that the second carrying plate 10013 enters the suspended lower space of the fiberboard; the press system 8 then releases the fiberboard and the power motor 701 rotates in reverse to effect return travel of the first carrier plate 1009 and the second carrier plate 10013, thus effecting discharge of the fiberboard.

The agitator 609 bottom surface is provided with crisscross plectrum, and the outer ring face of connecting rod is provided with the stirring rod.

The mixed powder is convenient to form a staggered channel in the stirring process, and the mixing of silicate powder and fiber powder is facilitated.

The telescopic shaft 1004 is composed of two connecting rods, wherein a convex strip is arranged on the outer ring surface of the connecting rod close to the seventh bevel gear 1005 and can slide relatively with the connecting rod close to the sixth bevel gear 1001, and meanwhile, a convex strip is also arranged on the outer ring surface of the connecting rod close to the sixth bevel gear 1001.

Control of the rotation of the sixth bevel gear 1001 is facilitated.

Although embodiments of the present invention have been shown and described, it would be appreciated by those skilled in the art that changes may be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the claims and their equivalents.

Claims (6)

1. A silicate fiber board manufacturing device for homogenizing powder distribution comprises a bottom column, a bottom plate, a controller and a portal frame; the method is characterized in that: the system also comprises a bearing system, a mixing system, a transfer system, an extrusion system, a powder spraying system and a discharging system; the bottom column is fixedly connected with the bottom plate; the bottom plate is connected with the bearing system; the bottom plate is fixedly connected with the portal frame; the bottom plate is connected with the transfer system; the bottom plate is connected with the extrusion system; the bottom plate is sequentially connected with the powder spraying system and the discharging system; the controller is connected with the portal frame; the bearing system is connected with the transfer system; the portal frame is connected with the mixing system; the portal frame is connected with the transfer system; the mixing system is connected with the transfer system;

the bearing system comprises a first support frame, a fixed plate, a first electric sliding rail, a sliding block, a carrying box and a first flat gear; the first support frame is connected with the transfer system; the first support frame is fixedly connected with the fixed plate; the first support frame is fixedly connected with the bottom plate; the fixed plate is connected with the first electric sliding rail through bolts; the first electric sliding rail is in sliding connection with the sliding block; the first support frame, the fixed plate, the first electric sliding rail and the sliding block are symmetrically provided with two groups; the sliding block is rotationally connected with the carrying box; the carrying box is fixedly connected with the first flat gear; the mixing system comprises a first bevel gear, a first rotating shaft, a first driving wheel, a second driving wheel, a first connecting shaft, a first sleeve shaft, a first supporting plate, a first electric push rod and a stirrer; the first bevel gear is fixedly connected with the first rotating shaft; the first bevel gear is connected with the transfer system; the first rotating shaft is fixedly connected with the first driving wheel; the first rotating shaft is rotationally connected with the portal frame through a bracket; the outer ring surface of the first driving wheel is in driving connection with the second driving wheel through a belt; the second driving wheel is fixedly connected with the first connecting shaft; the first connecting shaft is connected with the first sleeve shaft; the first connecting shaft is rotationally connected with the portal frame; the first sleeve shaft is rotationally connected with the first supporting plate; the first sleeve shaft is fixedly connected with the stirrer; the first supporting plate is fixedly connected with the first electric push rod; the first electric push rod is connected with the portal frame through bolts;

the powder spraying system is provided with a third support frame, a storage box, a first conveying pipe, a fan, a second conveying pipe, a powder sprayer and a second electric sliding rail; the third support frame is fixedly connected with the storage box; the third support frame is connected with the fan through bolts; the third support frame is fixedly connected with the second electric sliding rail; the third support frame is fixedly connected with the bottom plate; the storage box is connected with the first conveying pipe through bolts; the first conveying pipe is connected with the fan through bolts; the fan is connected with the second conveying pipe through bolts; the second material conveying pipe is fixedly connected with the powder sprayer; the powder sprayer is in sliding connection with the second electric sliding rail.

2. A silicate fiberboard making apparatus for homogenizing powder distribution as defined in claim 1, wherein: the transfer system comprises a power motor, an output shaft, a worm, a second bevel gear, a third driving wheel, a fourth driving wheel, a second connecting shaft, a second sleeve shaft, a second flat gear, a second supporting plate, a second electric push rod, a third bevel gear, a worm wheel, a third connecting shaft, a third sleeve shaft, a fourth bevel gear, a third supporting plate, a third electric push rod, a fifth bevel gear, a first screw rod, a limiting rod, a transport case and an electric valve; the power motor is fixedly connected with the output shaft; the power motor is connected with the bottom plate through bolts; the output shaft is fixedly connected with the worm, the second bevel gear and the third driving wheel in sequence; the output shaft is rotationally connected with the bottom plate through a bracket; the worm is meshed with the worm wheel; the outer ring surface of the third driving wheel is in driving connection with the fourth driving wheel through a belt; the second connecting shaft is fixedly connected with the fourth driving wheel and the third bevel gear in sequence; the second connecting shaft is connected with the second sleeve shaft; the second connecting shaft is rotationally connected with the portal frame; the second sleeve shaft is fixedly connected with a second flat gear; the second sleeve shaft is rotationally connected with the second supporting plate; the second supporting plate is fixedly connected with the second electric push rod; the second electric push rod is connected with the first support frame through bolts; the third bevel gear is meshed with the first bevel gear; the worm wheel is fixedly connected with the third connecting shaft; the third connecting shaft is connected with a third sleeve shaft; the third connecting shaft is rotationally connected with the bottom plate; the third sleeve shaft is fixedly connected with a fourth bevel gear; the third sleeve shaft is rotationally connected with the third supporting plate; the third supporting plate is fixedly connected with a third electric push rod; the third electric push rod is connected with the bottom plate through a bracket through a bolt; a fifth bevel gear is arranged above the fourth bevel gear; the fifth bevel gear is fixedly connected with the first screw rod; the first screw rod is connected with the transport case in a screwing way; the first screw rod is rotationally connected with the bottom plate through a bracket; the limiting rod is in sliding connection with the transport case; the limiting rod is fixedly connected with the bottom plate through a bracket; an electric valve is arranged in the transport case.

3. A silicate fiberboard making apparatus for homogenizing powder distribution as defined in claim 2, wherein: the extrusion system comprises a plate making die, a heating block, a top block, a fourth electric push rod, a second supporting frame, a hydraulic rod and an extrusion plate; the outer surface of the plate-making die is provided with a heating block; the plate making die is in sliding connection with the top block; the plate making die is fixedly connected with the bottom plate; the top block is fixedly connected with the fourth electric push rod; the fourth electric push rod is connected with the bottom plate through a bolt; the top block and the fourth electric push rod are provided with two groups; the side surface of the fourth electric push rod is provided with a second supporting frame; the second support frame is connected with the hydraulic rod through bolts; the second support frame is fixedly connected with the bottom plate; the hydraulic rod is fixedly connected with the extrusion plate; the hydraulic rod is provided with two groups.

4. A silicate fiberboard making apparatus for homogenizing powder distribution according to claim 3, characterized in that: the discharging system comprises a sixth bevel gear, a fourth supporting plate, a fifth electric push rod, a telescopic shaft, a seventh bevel gear, an eighth bevel gear, a second screw rod, a fifth driving wheel, a first carrying plate, a first straight sliding rail, a sixth driving wheel, a third screw rod, a second carrying plate and a second straight sliding rail; the sixth bevel gear is fixedly connected with the telescopic shaft; the fourth supporting plate is rotationally connected with the telescopic shaft; the fourth supporting plate is fixedly connected with the fifth electric push rod; the fifth electric push rod is connected with the bottom plate through a bolt; the telescopic shaft is fixedly connected with a seventh bevel gear; the telescopic shaft is rotationally connected with the bottom plate; the seventh bevel gear is meshed with the eighth bevel gear; the second screw rod is fixedly connected with an eighth bevel gear and a fifth driving wheel in sequence; the second screw rod is screwed with the first carrying plate; the second screw rod is rotationally connected with the first straight sliding rail; the outer ring surface of the fifth driving wheel is in driving connection with the sixth driving wheel through a belt; the first carrying plate is in sliding connection with the first straight sliding rail; the first straight sliding rail is fixedly connected with the bottom plate; the sixth driving wheel is fixedly connected with the third screw rod; the third screw rod is screwed with the second carrying plate; the second carrying plate is in sliding connection with the second straight slide rail; the second straight slide rail is fixedly connected with the bottom plate.

5. A silicate fiberboard making apparatus for homogenizing powder distribution in accordance with claim 4, wherein: the stirring device comprises a stirring rod, a stirring rod and a stirring rod.

6. A silicate fiberboard making apparatus for homogenizing powder distribution in accordance with claim 5, wherein: the telescopic shaft consists of two connecting rods, a convex strip is arranged on the outer ring surface of the connecting rod close to the seventh bevel gear and can slide relatively with the connecting rod close to the sixth bevel gear, and meanwhile, a convex strip is also arranged on the outer ring surface of the connecting rod close to the sixth bevel gear.