CN111319126A

CN111319126A - Fireproof substrate processing device

Info

Publication number: CN111319126A
Application number: CN202010189288.7A
Authority: CN
Inventors: 张海花
Original assignee: 张海花
Current assignee: Shaanxi Haiheng Industrial Co.,Ltd.
Priority date: 2020-03-18
Filing date: 2020-03-18
Publication date: 2020-06-23
Anticipated expiration: 2040-03-18
Also published as: CN111319126B

Abstract

The invention relates to a fireproof material, in particular to a fireproof base material processing device. The invention aims to provide a fireproof base material processing device. A fireproof base material processing device comprises a support frame, a control screen, a motor, a mortar filtering mechanism, a material homogenizing mechanism and a vibrating mechanism; a control screen is arranged in the middle right part of the support frame; the right part of the top end of the support frame is provided with a motor; and a mortar filtering mechanism is arranged at the left top part in the supporting frame. According to the invention, the large-particle sand stones which are not crushed in the fireproof heat-insulation mortar are screened out, so that the large-particle sand stones are prevented from damaging the shape of the paved mortar layer, the mortar layer is leveled, cracks caused by uneven solidification of different parts of mortar are prevented, the paved mortar is shaken, and the effects of large gaps generated inside and influence on fireproof quality are avoided.

Description

Fireproof substrate processing device

Technical Field

The invention relates to a fireproof material, in particular to a fireproof base material processing device.

Background

The fireproof thermal insulation mortar is a thermal insulation mortar material which is produced by processing inorganic thermal insulation materials such as vitrified micro-beads, expanded perlite and the like which have light volume weight, small heat conductivity coefficient and non-inflammability as main raw materials with cement, redispersible rubber powder and polymer additives according to a certain formula proportion. The fireproof heat-insulating mortar is suitable for making a leveling layer fireproof layer, a fireproof layer and a fireproof heat-insulating layer at a structural heat bridge position outside an organic heat-insulating material layer so as to improve the heat-insulating property and the fireproof property of heat-insulating engineering. It can also be used for the fire-proof heat-insulating engineering of the outer wall with high fire-proof requirement of building, the outer wall and the inner and outer walls of the outer wall. It can also be used as heat insulating layer for floor radiation heating and heat and sound insulating layer for floor system.

In the construction of the fireproof heat-insulating mortar of the fireproof base material in the prior art, the sand is usually crushed into mortar powder and then added with water for stirring, and then the mortar powder is directly coated on the surface of the base material, but because the mortar still contains large-particle sand which is partially completely crushed, and the problem of uneven thickness exists when the mortar is coated on the surface of the base material, the mortar in different parts is not uniformly solidified, and cracks are generated inside the mortar.

Consequently, need research and development one kind at present through screening out the not kibbling large granule grit in the fire prevention heat preservation mortar, avoid large granule grit to destroy the mortar layer shape of spreading, carry out the average material to the mortar layer simultaneously and trowel, prevent that different partial mortar from solidifying inhomogeneous production crack, shake to the mortar of spreading, avoid inside great clearance that produces, influence fire prevention effect's fire prevention substrate processingequipment, overcome among the prior art because still contain the part in the mortar for broken complete large granule grit, paint the mortar to the substrate surface simultaneously and have the uneven problem of thickness, can lead to different partial mortar to solidify inhomogeneously, inside cracked shortcoming that produces.

Disclosure of Invention

The invention aims to overcome the defects that different parts of mortar are not uniformly solidified and cracks are generated inside the mortar due to the fact that the mortar still contains part of large-particle gravels which are completely broken and the problem of nonuniform thickness of the mortar coated on the surface of a base material is solved.

The invention is achieved by the following specific technical means:

a fireproof base material processing device comprises a support frame, a control screen, a motor, a mortar filtering mechanism, a material homogenizing mechanism and a vibrating mechanism; a control screen is arranged in the middle right part of the support frame; the right part of the top end of the support frame is provided with a motor; a mortar filtering mechanism is arranged at the left top part in the supporting frame; the middle right part of the inner top of the supporting frame is provided with a material homogenizing mechanism, and the top of the right end of the material homogenizing mechanism is connected with a motor; the top of the left end of the homogenizing mechanism is connected with the mortar filtering mechanism; the right part is provided with the mechanism of trembling in the support frame inner bottom to tremble the mechanism top right part and be connected with the mixing mechanism.

Furthermore, the mortar filtering mechanism comprises a first bevel gear, a second bevel gear, a first driving wheel, a second driving wheel, a third driving wheel, a telescopic rod, a first flat gear, a second flat gear, a screw rod, a bearing block, a filter screen, a feeding pipe, a conveying pipe, a switch valve, a fourth driving wheel, a first driving rod, a third flat gear, a first gear ring, a second driving rod, a fifth driving wheel, a third driving rod, a fourth flat gear, a second gear ring, a fourth driving rod, a fifth driving rod, a thorn brush and a material storage box; the rear part of the left end of the first bevel gear is meshed with the second bevel gear; the left end axis of the first bevel gear is rotationally connected with the second transmission wheel; the rear end axle center of the second bevel gear is rotationally connected with the first transmission wheel; the middle part of the bottom end of the first driving wheel is in transmission connection with a fourth driving wheel through a belt; the middle part of the bottom end of the second driving wheel is in transmission connection with a third driving wheel through a belt; the right end axle center of the third driving wheel is connected with the telescopic rod; the right end axis of the telescopic rod is connected with the first flat gear; the top end of the first flat gear is meshed with the second flat gear; the right end axle center of the second flat gear is rotationally connected with the screw rod; a bearing block is arranged at the right part of the outer surface of the screw rod; the front end of the bearing block is connected with the filter screen; the top end and the bottom end of the filter screen are both connected with a feeding pipe; a material conveying pipe is arranged at the bottom of the right end of the feeding pipe; a switch valve is arranged at the left top of the material conveying pipe; the front end axle center of the fourth driving wheel is rotationally connected with the first driving rod; the middle part of the left end of the fourth driving wheel is in transmission connection with the fifth driving wheel through a belt; the right part of the front end of the first transmission rod is connected with the third horizontal gear; the right end of the third spur gear is meshed with the first gear ring; the front end axle center of the third horizontal gear is in transmission connection with the second transmission rod; the bottom of the front end of the second transmission rod is connected with a fifth transmission rod; the axle center of the front end of the fifth driving wheel is rotationally connected with the third driving rod; the right part of the front end of the third transmission rod is connected with a fourth flat gear; the right end of the fourth flat gear is meshed with the second gear ring; the axle center of the front end of the fourth flat gear is in transmission connection with a fourth transmission rod, and the bottom of the front end of the fourth transmission rod is connected with a fifth transmission rod; a thorn brush is arranged in the middle of the bottom end of the fifth transmission rod; the bottom of the thorn brush is provided with a material storage box; the right end axis of the first bevel gear is connected with the material homogenizing mechanism; the rear end shaft center of the first driving wheel is connected with the supporting frame through the mounting seat; the rear end axle center of the second driving wheel is connected with the supporting frame through the mounting seat; the rear end axle center of the third driving wheel is connected with the supporting frame through the mounting seat; the left part of the outer surface of the telescopic rod is connected with the supporting frame through the mounting seat; the left part of the outer surface of the screw rod is connected with the support frame through the mounting seat; the bottom end of the feeding pipe is connected with the supporting frame through the mounting seat; the bottom end of the conveying pipe is connected with the supporting frame through the mounting seat; the rear end axle center of the fourth driving wheel is connected with the supporting frame through the mounting seat; the top end of the first gear ring is connected with the support frame through the mounting seat; the rear end axle center of the fifth driving wheel is connected with the supporting frame through a mounting seat; the top end of the second gear ring is connected with the supporting frame through the mounting seat; the bottom end of the storage box is connected with the support frame.

Furthermore, the material homogenizing mechanism comprises a sixth driving wheel, a third bevel gear, a fourth bevel gear, a seventh driving wheel, an eighth driving wheel, a fifth flat gear, a special-shaped sliding plate, a first sliding rail, a flat sliding plate, a second sliding rail, a sixth driving rod and a mortar brush; the axle center of the left end of the sixth transmission wheel is rotationally connected with the third bevel gear; the rear part of the left end of the third bevel gear is meshed with the fourth bevel gear; the axle center at the rear end of the fourth bevel gear is rotationally connected with a seventh driving wheel; the middle part of the bottom end of the seventh driving wheel is in transmission connection with the eighth driving wheel; the rear end axle center of the eighth driving wheel is rotationally connected with the fifth flat gear; the bottom end of the fifth flat gear is connected with the special-shaped sliding plate; the rear part of the special-shaped sliding plate is in sliding connection with the first sliding rail; the middle part of the bottom end of the special-shaped sliding plate is connected with a sixth transmission rod; the rear end of the first sliding rail is connected with the smooth plate; the rear part of the smooth plate is connected with the second slide rail in a sliding way; a mortar brush is arranged in the middle of the bottom end of the sixth transmission rod; the right end axle center of the sixth driving wheel is connected with a motor; the bottom end of the sixth driving wheel is connected with the shaking mechanism; the left end axis of the third bevel gear is connected with the first bevel gear; the rear end axle center of the seventh driving wheel is connected with the supporting frame through the mounting seat; the front end axle center of the eighth driving wheel is connected with the supporting frame through a mounting seat; the top and the bottom of the right end of the second slide rail are both connected with the support frame.

Furthermore, the shaking mechanism comprises a ninth driving wheel, a fifth bevel gear, a sixth bevel gear, a tenth driving wheel, an eleventh driving wheel, a first special-shaped driving rod, a seventh driving rod, a first fixed column, a first spring, an eighth driving rod, a first sleeve head, a twelfth driving wheel, a second special-shaped driving rod, a ninth driving rod, a second fixed column, a second spring, a tenth driving rod and a second sleeve head; the shaft center of the left end of the ninth transmission wheel is rotationally connected with the fifth bevel gear; the rear part of the left end of the fifth bevel gear is meshed with the sixth bevel gear; the axle center at the rear end of the sixth bevel gear is rotationally connected with a tenth transmission wheel; the middle part of the left end of the tenth driving wheel is in transmission connection with the eleventh driving wheel through a belt; the front end axle center of the eleventh transmission wheel is rotationally connected with the first special-shaped transmission rod; the middle part of the left end of the eleventh driving wheel is in transmission connection with the twelfth driving wheel through a belt; a seventh transmission rod is arranged at the bottom end of the first special-shaped transmission rod; a first fixing column is arranged at the left bottom of the seventh transmission rod; the left bottom of the seventh transmission rod is connected with the first spring, and the inner surface of the first spring is connected with the first fixing column; the left part of the front end of the seventh transmission rod is connected with the eighth transmission rod; a first sleeve head is arranged in the middle of the top end of the eighth transmission rod; the axle center of the front end of the twelfth transmission wheel is rotationally connected with the second special-shaped transmission rod; a ninth transmission rod is arranged at the bottom end of the second special-shaped transmission rod; a second fixing column is arranged at the left bottom of the ninth transmission rod; the left bottom of the ninth transmission rod is connected with a second spring, and the inner surface of the second spring is connected with a second fixing column; the left part of the front end of the ninth transmission rod is connected with the tenth transmission rod; a second sleeve head is arranged in the middle of the top end of the tenth transmission rod; the top end of the ninth transmission wheel is connected with the sixth transmission wheel; the right end axle center of the ninth driving wheel is connected with the supporting frame through a mounting seat; the rear end axle center of the tenth driving wheel is connected with the supporting frame through the mounting seat; the rear end axle center of the eleventh transmission wheel is connected with the supporting frame through a mounting seat; the right part of the rear end of the seventh transmission rod is connected with the support frame through a mounting seat; the bottom end of the first fixing column is connected with the supporting frame; the middle top of the outer surface of the eighth transmission rod is connected with the support frame through the mounting seat; the rear end axle center of the twelfth transmission wheel is connected with the supporting frame through the mounting seat; the right part of the rear end of the ninth transmission rod is connected with the support frame through the mounting seat; the bottom end of the second fixing column is connected with the supporting frame; the top of the outer surface of the tenth transmission rod is connected with the supporting frame through the mounting seat.

Furthermore, the motion trail of the thorn brush is triangular.

Furthermore, the fifth flat gear is matched with the convex block at the front middle part of the special-shaped sliding plate.

Furthermore, the first special-shaped driving rod and the seventh driving rod are always tightly attached.

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

in order to solve the problems that in the prior art, part of large-particle sand stones which are completely broken are still contained in mortar, and the mortar applied on the surface of a base material has uneven thickness, so that different parts of mortar are unevenly solidified and cracks are generated inside the mortar, a mortar filtering mechanism is designed, the fireproof heat-preservation mortar is screened through the mortar filtering mechanism, the large-particle sand stones which are not crushed inside the mortar are screened out, the large-particle sand stones which are not crushed in the fireproof heat-preservation mortar are screened out, the effect of preventing the large-particle sand stones from damaging the shape of the paved mortar layer is achieved, a material equalizing mechanism is designed, the mortar piled on the surface of the base material is leveled through the material equalizing mechanism, the effect of equalizing and leveling the mortar layer and preventing the different parts of mortar from being unevenly solidified and generating cracks is achieved, a shaking mechanism is designed, and the paved mortar is shaken to remove bubbles, the effect of shaking the paved mortar is achieved, the phenomenon that a large gap is generated inside the mortar, and the fireproof effect is affected is avoided.

Drawings

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

FIG. 2 is a schematic structural view of a mortar filtering mechanism according to the present invention;

FIG. 3 is a schematic structural diagram of a material homogenizing mechanism according to the present invention;

fig. 4 is a schematic structural diagram of the shaking mechanism of the present invention.

The labels in the figures are: 1-a support frame, 2-a control screen, 3-a motor, 4-a mortar filtering mechanism, 5-a material homogenizing mechanism, 6-a shaking mechanism, 401-a first bevel gear, 402-a second bevel gear, 403-a first driving wheel, 404-a second driving wheel, 405-a third driving wheel, 406-a telescopic rod, 407-a first flat gear, 408-a second flat gear, 409-a screw rod, 4010-a bearing block, 4011-a filter screen, 4012-a feeding pipe, 4013-a feeding pipe, 4014-a switch valve, 4015-a fourth driving wheel, 4016-a first driving rod, 4017-a third flat gear, 4018-a first gear ring, 4019-a second driving rod, 4020-a fifth driving wheel, 4021-a third driving rod, 4022-a fourth flat gear and 3-a second gear ring, 4024-a fourth transmission rod, 4025-a fifth transmission rod, 4026-a barbed brush, 4027-a storage box, 501-a sixth transmission wheel, 502-a third bevel gear, 503-a fourth bevel gear, 504-a seventh transmission wheel, 505-an eighth transmission wheel, 506-a fifth flat gear, 507-a special-shaped sliding plate, 508-a first sliding rail, 509-a flat sliding plate, 5010-a second sliding rail, 5011-a sixth transmission rod, 5012-a mortar brush, 601-a ninth transmission wheel, 602-a fifth bevel gear, 603-a sixth bevel gear, 604-a tenth transmission wheel, 605-an eleventh transmission wheel, 606-a first special-shaped transmission rod, 607-a seventh transmission rod, 608-a first fixed column, 609-a first spring, 6010-an eighth transmission rod, 6011-a first sleeve head, 6012-a twelfth driving wheel, 6013-a second special-shaped driving rod, 6014-a ninth driving rod, 6015-a second fixed column, 6016-a second spring, 6017-a tenth driving rod and 6018-a second sleeve head.

Detailed Description

The invention is further described below with reference to the figures and examples.

Examples

A fireproof base material processing device is shown in figures 1-4 and comprises a support frame 1, a control screen 2, a motor 3, a mortar filtering mechanism 4, a material homogenizing mechanism 5 and a vibrating mechanism 6; a control screen 2 is arranged in the right middle of the support frame 1; the right part of the top end of the support frame 1 is provided with a motor 3; a mortar filtering mechanism 4 is arranged at the left top part in the support frame 1; the middle right part of the inner top of the support frame 1 is provided with a material homogenizing mechanism 5, and the top of the right end of the material homogenizing mechanism 5 is connected with the motor 3; the top of the left end of the homogenizing mechanism 5 is connected with the mortar filtering mechanism 4; the right part is provided with the mechanism 6 that shakes in support frame 1 insole to 6 top right parts that shake the mechanism are connected with the homocline mechanism 5.

The mortar filtering mechanism 4 comprises a first bevel gear 401, a second bevel gear 402, a first driving wheel 403, a second driving wheel 404, a third driving wheel 405, a telescopic rod 406, a first flat gear 407, a second flat gear 408, a screw rod 409, a bearing block 4010, a filter screen 4011, a feeding pipe 4012, a conveying pipe 4013, a switch valve 4014, a fourth driving wheel 4015, a first driving rod 4016, a third flat gear 4017, a first gear ring 4018, a second driving rod 4019, a fifth driving wheel 4020, a third driving rod 4021, a fourth flat gear 4022, a second gear ring 4023, a fourth driving rod 4024, a fifth driving rod 4025, a barbed brush 4026 and a storage box 4027; the rear part of the left end of the first bevel gear 401 is meshed with the second bevel gear 402; the left end axis of the first bevel gear 401 is rotationally connected with a second transmission wheel 404; the rear end axis of the second bevel gear 402 is rotationally connected with the first transmission wheel 403; the middle part of the bottom end of the first driving wheel 403 is in driving connection with a fourth driving wheel 4015 through a belt; the middle part of the bottom end of the second driving wheel 404 is in transmission connection with a third driving wheel 405 through a belt; the right end axle center of the third driving wheel 405 is connected with the telescopic rod 406; the right end axis of the telescopic rod 406 is connected with a first flat gear 407; the top end of the first flat gear 407 is meshed with the second flat gear 408; the right end axis of the second flat gear 408 is rotationally connected with the screw rod 409; a bearing block 4010 is arranged on the right part of the outer surface of the screw rod 409; the front end of the bearing block 4010 is connected with a filter screen 4011; the top end and the bottom end of the filter screen 4011 are both connected with a feed pipe 4012; a material conveying pipe 4013 is arranged at the bottom of the right end of the material inlet pipe 4012; a switch valve 4014 is arranged at the left top of the material conveying pipe 4013; the front end axle center of the fourth driving wheel 4015 is rotationally connected with the first driving rod 4016; the middle part of the left end of the fourth driving wheel 4015 is in transmission connection with a fifth driving wheel 4020 through a belt; the right part of the front end of the first transmission rod 4016 is connected with a third horizontal gear 4017; the right end of the third gear 4017 is engaged with the first gear 4018; the front end axle center of the third horizontal gear 4017 is in transmission connection with a second transmission rod 4019; the bottom of the front end of the second transmission rod 4019 is connected with a fifth transmission rod 4025; the front end axle center of the fifth transmission wheel 4020 is rotationally connected with the third transmission rod 4021; the right part of the front end of the third transmission rod 4021 is connected with a fourth flat gear 4022; the right end of the fourth flat gear 4022 is meshed with the second gear ring 4023; the front end axis of the fourth flat gear 4022 is in transmission connection with a fourth transmission rod 4024, and the bottom of the front end of the fourth transmission rod 4024 is connected with a fifth transmission rod 4025; a barbed brush 4026 is arranged in the middle of the bottom end of the fifth transmission rod 4025; a material storage box 4027 is arranged at the bottom of the thorn brush 4026; the right end axis of the first bevel gear 401 is connected with the homogenizing mechanism 5; the rear end axle center of the first driving wheel 403 is connected with the support frame 1 through a mounting seat; the rear end axle center of the second driving wheel 404 is connected with the supporting frame 1 through a mounting seat; the rear end axle center of the third driving wheel 405 is connected with the supporting frame 1 through a mounting seat; the left part of the outer surface of the telescopic rod 406 is connected with the support frame 1 through a mounting seat; the left part of the outer surface of the screw rod 409 is connected with the support frame 1 through a mounting seat; the bottom end of the feeding pipe 4012 is connected with the support frame 1 through a mounting seat; the bottom end of the delivery pipe 4013 is connected with the support frame 1 through a mounting seat; the rear end axle center of the fourth driving wheel 4015 is connected with the supporting frame 1 through a mounting seat; the top end of the first gear ring 4018 is connected with the support frame 1 through a mounting seat; the rear end axle center of the fifth driving wheel 4020 is connected with the support frame 1 through a mounting seat; the top end of the second gear ring 4023 is connected with the support frame 1 through a mounting seat; the bottom of the storage case 4027 is connected with the support frame 1.

The material homogenizing mechanism 5 comprises a sixth driving wheel 501, a third bevel gear 502, a fourth bevel gear 503, a seventh driving wheel 504, an eighth driving wheel 505, a fifth flat gear 506, a special-shaped sliding plate 507, a first sliding rail 508, a flat sliding plate 509, a second sliding rail 5010, a sixth driving rod 5011 and a mortar brush 5012; the left end axle center of the sixth transmission wheel 501 is rotationally connected with the third bevel gear 502; the rear part of the left end of the third bevel gear 502 is meshed with a fourth bevel gear 503; the rear end axle center of the fourth bevel gear 503 is rotatably connected with a seventh driving wheel 504; the middle part of the bottom end of the seventh driving wheel 504 is in transmission connection with an eighth driving wheel 505; the rear end axle center of the eighth driving wheel 505 is rotationally connected with the fifth flat gear 506; the bottom end of the fifth flat gear 506 is connected with a special-shaped sliding plate 507; the rear part of the special-shaped sliding plate 507 is in sliding connection with a first sliding rail 508; the middle part of the bottom end of the special-shaped sliding plate 507 is connected with a sixth transmission rod 5011; the rear end of the first slide rail 508 is connected with a smooth plate 509; the rear part of the flat sliding plate 509 is in sliding connection with a second sliding rail 5010; a mortar brush 5012 is arranged in the middle of the bottom end of the sixth transmission rod 5011; the axle center of the right end of the sixth transmission wheel 501 is connected with the motor 3; the bottom end of the sixth driving wheel 501 is connected with the shaking mechanism 6; the left end axis of the third bevel gear 502 is connected with the first bevel gear 401; the rear end axle center of the seventh driving wheel 504 is connected with the supporting frame 1 through a mounting seat; the front end axle center of the eighth driving wheel 505 is connected with the supporting frame 1 through a mounting seat; the top and the bottom of the right end of the second sliding rail 5010 are both connected with the support frame 1.

The shaking mechanism 6 comprises a ninth driving wheel 601, a fifth bevel gear 602, a sixth bevel gear 603, a tenth driving wheel 604, an eleventh driving wheel 605, a first special-shaped driving rod 606, a seventh driving rod 607, a first fixed column 608, a first spring 609, an eighth driving rod 6010, a first sleeve 6011, a twelfth driving wheel 6012, a second special-shaped driving rod 6013, a ninth driving rod 6014, a second fixed column 6015, a second spring 6016, a tenth driving rod 6017 and a second sleeve 6018; the left end axis of the ninth driving wheel 601 is rotatably connected with a fifth bevel gear 602; the rear part of the left end of the fifth bevel gear 602 is meshed with a sixth bevel gear 603; the rear end axle center of the sixth bevel gear 603 is rotationally connected with a tenth transmission wheel 604; the middle part of the left end of the tenth transmission wheel 604 is in transmission connection with an eleventh transmission wheel 605 through a belt; the front end axle center of the eleventh driving wheel 605 is rotationally connected with the first special-shaped driving rod 606; the middle part of the left end of the eleventh driving wheel 605 is in transmission connection with a twelfth driving wheel 6012 through a belt; the bottom end of the first special-shaped driving rod 606 is provided with a seventh driving rod 607; a first fixing column 608 is arranged at the left bottom of the seventh transmission rod 607; the left bottom of the seventh transmission rod 607 is connected with a first spring 609, and the inner surface of the first spring 609 is connected with a first fixing column 608; the left part of the front end of the seventh transmission rod 607 is connected with the eighth transmission rod 6010; a first sleeve head 6011 is arranged in the middle of the top end of the eighth transmission rod 6010; the axle center of the front end of the twelfth driving wheel 6012 is rotatably connected with a second special-shaped driving rod 6013; a ninth transmission rod 6014 is arranged at the bottom end of the second special-shaped transmission rod 6013; a second fixing column 6015 is arranged at the left bottom of the ninth transmission rod 6014; the left bottom of the ninth transmission rod 6014 is connected with a second spring 6016, and the inner surface of the second spring 6016 is connected with a second fixing column 6015; the left part of the front end of the ninth transmission rod 6014 is connected with a tenth transmission rod 6017; a second sleeve head 6018 is arranged in the middle of the top end of the tenth transmission rod 6017; the top end of the ninth driving wheel 601 is connected with a sixth driving wheel 501; the right end axle center of the ninth transmission wheel 601 is connected with the support frame 1 through a mounting seat; the rear end axle center of the tenth transmission wheel 604 is connected with the supporting frame 1 through a mounting seat; the rear end axle center of the eleventh transmission wheel 605 is connected with the supporting frame 1 through a mounting seat; the right part of the rear end of the seventh transmission rod 607 is connected with the support frame 1 through a mounting seat; the bottom end of the first fixing column 608 is connected with the support frame 1; the middle top of the outer surface of the eighth transmission rod 6010 is connected with the support frame 1 through a mounting seat; the rear end axle center of the twelfth driving wheel 6012 is connected with the supporting frame 1 through a mounting seat; the right part of the rear end of the ninth transmission rod 6014 is connected with the support frame 1 through a mounting seat; the bottom end of the second fixing column 6015 is connected with the support frame 1; the top of the outer surface of the tenth transmission rod 6017 is connected to the support frame 1 through a mounting seat.

The motion trail of the brush 4026 is triangular.

The fifth flat gear 506 is matched with a convex block at the front middle part of the special-shaped sliding plate 507.

The first special-shaped transmission rod 606 and the seventh transmission rod 607 are always tightly attached.

The working principle is as follows: when in use, the device is horizontally placed at a position to be used through the support frame 1, the power supply is switched on, the device is prepared through the control screen 2, quantitative fireproof heat-preservation mortar is added into the feeding pipe 4012, the motor 3 is started, the fireproof heat-preservation mortar is screened through the mortar filtering mechanism 4, large-particle gravels which are not crushed in the mortar are screened out and transported to the surface of the base material, the mortar piled on the surface of the base material is leveled through the material equalizing mechanism 5, then the paved mortar is vibrated through the vibrating mechanism 6 to remove air bubbles, finally, a fireproof base material finished product is obtained, the device screens out the large-particle gravels which are not crushed in the fireproof heat-preservation mortar, the large-particle gravels are prevented from damaging the shape of the paved mortar layer, the mortar layer is leveled through material equalizing, cracks caused by uneven solidification of different parts of the mortar are prevented, the paved mortar is vibrated, and large gaps are prevented from being, affecting the fire protection effect.

When a certain amount of fireproof heat-preservation mortar is put into the feeding pipe 4012, large-particle gravels are screened out through the filter screen 4011, after a large amount of gravels are accumulated on the filter screen 4011, the first bevel gear 401 rotates to drive the second bevel gear 402 to rotate, the first driving wheel 403 is driven to rotate at the same time, the second driving wheel 404 is driven to rotate, the third driving wheel 405 drives the first flat gear 407 to rotate through the telescopic rod 406 and the first flat gear 407 is meshed with the second flat gear 408 to rotate, at the moment, the telescopic rod 406 is in a telescopic state and drives the screw rod 409 to rotate, the filter screen 4011 is driven to move leftwards through the bearing block 4010, when the third driving wheel moves to the upper part of the storage box 4027, the telescopic rod 406 is contracted, the filter screen 4011 stops moving, meanwhile, the first driving wheel 403 rotates to drive the fourth driving wheel 4015 to rotate, and further drives the first driving rod 4016 to enable the, the third flat gear 4017 drives the second transmission rod 4019, meanwhile, the fourth transmission wheel 4015 rotates to drive the fifth transmission wheel 4020 to rotate, further, the third transmission rod 4021 is driven to drive the fourth flat gear 4022 to do circular motion in the second gear ring 4023, the fourth flat gear 4022 drives the fourth transmission rod 4024, the fifth transmission rod 4025 makes triangular track motion under the synchronous rotation of the second transmission rod 4019 and the fourth transmission rod 4024, the barbed brush 4026 is synchronously driven to make triangular track motion, large-particle graved stones on the surface of the filter screen 4011 are scraped, the large-particle graved stones fall into the storage box 4027, when sufficient mortar is left in the feeding pipe 4012, the switch valve 4014 is drawn out, the mortar reaches the surface of a base material through the feeding pipe 4013, and the mechanism removes the large-particle graved stones which are not crushed in the fireproof heat-insulation mortar through screening, so that the shape of the paved mortar layer is prevented from being damaged.

When the mortar reaches the surface of the base material, the third bevel gear 502 is driven to rotate by the rotation of the sixth transmission wheel 501, the third bevel gear 502 is meshed with the fourth bevel gear 503 to rotate, the seventh transmission wheel 504 is driven to rotate, the eighth transmission wheel 505 is driven to rotate, the fifth flat gear 506 is driven to rotate at the same time, the special-shaped sliding plate 507 is driven to slide in the first sliding rail 508, when the left part of the front end of the special-shaped sliding plate 507 moves to the lower part of the fifth flat gear 506, the fifth flat gear 506 gives an upward force to the special-shaped sliding plate 507, the first sliding rail 508 is driven to slide upwards in the second sliding rail 5010 through the flat sliding plate 509, when the right part of the front end of the special-shaped sliding plate 507 moves to be in contact with the fifth flat gear 506, the fifth flat gear 506 gives a downward force to the special-shaped sliding plate 507, the first sliding rail 508 is driven to slide downwards in the second special-shaped sliding rail 5010 through the, the mortar brush 5012 synchronously moves in a rectangular track through the sixth transmission rod 5011, so that the mortar brush 5012 can level the mortar pile, the mechanism can level the mortar layer, and cracks caused by uneven solidification of different parts of mortar are prevented.

After the mortar layer is homogenized, the fifth bevel gear 602 is driven to rotate through the rotation of the ninth driving wheel 601, the fifth bevel gear 602 is meshed with the sixth bevel gear 603 to rotate, the tenth driving wheel 604 is driven to rotate, the eleventh driving wheel 605 is driven to rotate, the first special-shaped driving rod 606 is driven to rotate, when one end of the first special-shaped driving rod 606 with a small width is in contact with the seventh driving rod 607, the seventh driving rod 607 is extruded downwards through the first spring 609, the first fixing column 608 has a fixing function, when one end of the first special-shaped driving rod 606 with a large width is in contact with the seventh driving rod 607, the seventh driving rod 607 is restored to the original position, meanwhile, the left end of the seventh driving rod 607 gives an upward acceleration to the first sleeve head 6011 through the eighth driving rod 6010 through the elastic acting force of the first spring 609, and the first sleeve head 6011 generates a vibration force to the base material through the supporting frame 1, meanwhile, the eleventh driving wheel 605 rotates to drive the twelfth driving wheel 6012 to rotate, so as to drive the second special-shaped driving rod 6013 to rotate, when the end, with the small width, of the second special-shaped driving rod 6013 is in contact with the ninth driving rod 6014, the ninth driving rod 6014 is extruded downwards through the second spring 6016, the second fixing column 6015 plays a role in fixing, when the second special-shaped driving rod 6013 rotates to the end, with the large width, of the second special-shaped driving rod 6013 is in contact with the ninth driving rod 6014, so that the ninth driving rod 6014 is restored to the original position, meanwhile, the left end of the ninth driving rod 6014 gives an upward acceleration to the second sleeve 6018 through the tenth driving rod 6017 by the elastic acting force of the second spring 6016, so that the second sleeve 6018 generates a shaking force on the base material through the supporting frame 1, and the mechanism shakes the paved mortar to avoid large gaps inside.

The motion trail of the barbed brush 4026 is triangular, so that the barbed brush 4026 continuously scrapes sand from the filter screen 4011.

The fifth flat gear 506 is matched with a convex block at the front middle part of the special-shaped sliding plate 507, so that the special-shaped sliding plate 507 is driven to move in a rectangular shape when the fifth flat gear 506 rotates.

The first special-shaped transmission rod 606 and the seventh transmission rod 607 are always tightly attached to each other, so that the seventh transmission rod 607 can perform circular motion with the right end as the center of a circle.

The present application has been described in conjunction with specific embodiments, but it should be understood by those skilled in the art that these descriptions are intended to be illustrative, and not limiting. Various modifications and adaptations of the present application may occur to those skilled in the art based on the spirit and principles of the application and are within the scope of the application.

Claims

1. A fireproof base material processing device comprises a support frame (1), a control screen (2) and a motor (3), and is characterized by further comprising a mortar filtering mechanism (4), a material homogenizing mechanism (5) and a vibrating mechanism (6); a control screen (2) is arranged in the middle right part of the support frame (1); a motor (3) is arranged at the right part of the top end of the support frame (1); a mortar filtering mechanism (4) is arranged at the left top part in the supporting frame (1); a material homogenizing mechanism (5) is arranged at the middle right part of the inner top of the support frame (1), and the top of the right end of the material homogenizing mechanism (5) is connected with the motor (3); the top of the left end of the homogenizing mechanism (5) is connected with the mortar filtering mechanism (4); the right part in the inner bottom of the support frame (1) is provided with a vibrating mechanism (6), and the right part at the top end of the vibrating mechanism (6) is connected with a material homogenizing mechanism (5).

2. The fireproof substrate processing apparatus according to claim 1, wherein the mortar filtering mechanism (4) comprises a first bevel gear (401), a second bevel gear (402), a first driving wheel (403), a second driving wheel (404), a third driving wheel (405), a telescopic rod (406), a first pinion (407), a second pinion (408), a lead screw (409), a bearing block (4010), a filter screen (4011), a feeding pipe (4012), a feeding pipe (4013), a switch valve (4014), a fourth driving wheel (4015), a first driving rod (4016), a third pinion (4017), a first gear ring (4018), a second driving rod (4019), a fifth driving wheel (4020), a third driving rod (4021), a fourth pinion (4022), a second gear ring (4023), a fourth driving rod (4024), a fifth driving rod (4025), a barbed brush (4026) and a storage box (4027); the rear part of the left end of the first bevel gear (401) is meshed with the second bevel gear (402); the left end axis of the first bevel gear (401) is rotationally connected with a second transmission wheel (404); the rear end axle center of the second bevel gear (402) is rotationally connected with the first transmission wheel (403); the middle part of the bottom end of the first driving wheel (403) is in transmission connection with a fourth driving wheel (4015) through a belt; the middle part of the bottom end of the second driving wheel (404) is in transmission connection with a third driving wheel (405) through a belt; the right end axle center of the third driving wheel (405) is connected with an expansion link (406); the right end axis of the telescopic rod (406) is connected with a first flat gear (407); the top end of the first flat gear (407) is meshed with the second flat gear (408); the right end axle center of the second flat gear (408) is rotationally connected with the screw rod (409); a bearing block (4010) is arranged on the middle right part of the outer surface of the screw rod (409); the front end of the bearing block (4010) is connected with a filter screen (4011); the top end and the bottom end of the filter screen (4011) are both connected with a feeding pipe (4012); a material conveying pipe (4013) is arranged at the bottom of the right end of the material inlet pipe (4012); a switch valve (4014) is arranged at the left top of the material conveying pipe (4013); the front end axle center of the fourth driving wheel (4015) is rotationally connected with the first driving rod (4016); the middle part of the left end of the fourth driving wheel (4015) is in transmission connection with a fifth driving wheel (4020) through a belt; the right part of the front end of the first transmission rod (4016) is connected with a third horizontal gear (4017); the right end of the third gear (4017) is meshed with the first gear ring (4018); the front end axle center of the third horizontal gear (4017) is in transmission connection with a second transmission rod (4019); the bottom of the front end of the second transmission rod (4019) is connected with a fifth transmission rod (4025); the front end axle center of the fifth transmission wheel (4020) is rotationally connected with the third transmission rod (4021); the right part of the front end of the third transmission rod (4021) is connected with a fourth flat gear (4022); the right end of the fourth flat gear (4022) is meshed with the second gear ring (4023); the axle center of the front end of the fourth flat gear (4022) is in transmission connection with a fourth transmission rod (4024), and the bottom of the front end of the fourth transmission rod (4024) is connected with a fifth transmission rod (4025); a thorn brush (4026) is arranged in the middle of the bottom end of the fifth transmission rod (4025); a material storage box (4027) is arranged at the bottom of the thorn brush (4026); the right end axis of the first bevel gear (401) is connected with the material homogenizing mechanism (5); the rear end axle center of the first driving wheel (403) is connected with the support frame (1) through a mounting seat; the rear end axle center of the second driving wheel (404) is connected with the supporting frame (1) through a mounting seat; the rear end axle center of the third driving wheel (405) is connected with the supporting frame (1) through a mounting seat; the left part of the outer surface of the telescopic rod (406) is connected with the support frame (1) through a mounting seat; the left part of the outer surface of the screw rod (409) is connected with the support frame (1) through a mounting seat; the bottom end of the feeding pipe (4012) is connected with the support frame (1) through a mounting seat; the bottom end of the material conveying pipe (4013) is connected with the support frame (1) through a mounting seat; the rear end axle center of the fourth driving wheel (4015) is connected with the supporting frame (1) through a mounting seat; the top end of the first gear ring (4018) is connected with the support frame (1) through a mounting seat; the rear end axle center of the fifth transmission wheel (4020) is connected with the support frame (1) through a mounting seat; the top end of the second gear ring (4023) is connected with the support frame (1) through the mounting seat; the bottom end of the material storage box (4027) is connected with the support frame (1).

3. A fire-proof substrate processing device according to claim 2, characterized in that the material homogenizing mechanism (5) comprises a sixth transmission wheel (501), a third bevel gear (502), a fourth bevel gear (503), a seventh transmission wheel (504), an eighth transmission wheel (505), a fifth flat gear (506), a profiled sliding plate (507), a first sliding rail (508), a flat sliding plate (509), a second sliding rail (5010), a sixth transmission rod (5011) and a mortar brush (5012); the left end axis of the sixth transmission wheel (501) is rotationally connected with the third bevel gear (502); the rear part of the left end of the third bevel gear (502) is meshed with the fourth bevel gear (503); the rear end axle center of the fourth bevel gear (503) is rotationally connected with a seventh driving wheel (504); the middle part of the bottom end of the seventh driving wheel (504) is in transmission connection with an eighth driving wheel (505); the rear end axle center of the eighth driving wheel (505) is rotationally connected with the fifth flat gear (506); the bottom end of the fifth flat gear (506) is connected with a special-shaped sliding plate (507); the rear part of the special-shaped sliding plate (507) is in sliding connection with a first sliding rail (508); the middle part of the bottom end of the special-shaped sliding plate (507) is connected with a sixth transmission rod (5011); the rear end of the first slide rail (508) is connected with a smooth plate (509); the rear part of the smooth plate (509) is in sliding connection with a second sliding rail (5010); a mortar brush (5012) is arranged in the middle of the bottom end of the sixth transmission rod (5011); the right end axle center of the sixth transmission wheel (501) is connected with the motor (3); the bottom end of the sixth transmission wheel (501) is connected with the shaking mechanism (6); the left end axis of the third bevel gear (502) is connected with the first bevel gear (401); the rear end axle center of the seventh transmission wheel (504) is connected with the supporting frame (1) through a mounting seat; the front end axle center of the eighth driving wheel (505) is connected with the supporting frame (1) through a mounting seat; the top and the bottom of the right end of the second sliding rail (5010) are both connected with the support frame (1).

4. A fire-proof substrate processing apparatus according to claim 3, wherein the vibration mechanism (6) comprises a ninth transmission wheel (601), a fifth bevel gear (602), a sixth bevel gear (603), a tenth transmission wheel (604), an eleventh transmission wheel (605), a first special-shaped transmission rod (606), a seventh transmission rod (607), a first fixed column (608), a first spring (609), an eighth transmission rod (6010), a first set of heads (6011), a twelfth transmission wheel (6012), a second special-shaped transmission rod (6013), a ninth transmission rod (6014), a second fixed column (6015), a second spring (6016), a tenth transmission rod (6017) and a second set of heads (6018); the shaft center of the left end of the ninth transmission wheel (601) is rotationally connected with a fifth bevel gear (602); the rear part of the left end of the fifth bevel gear (602) is meshed with the sixth bevel gear (603); the rear end axle center of the sixth bevel gear (603) is rotationally connected with a tenth driving wheel (604); the middle part of the left end of the tenth driving wheel (604) is in transmission connection with an eleventh driving wheel (605) through a belt; the front end axle center of the eleventh driving wheel (605) is rotationally connected with the first special-shaped driving rod (606); the middle part of the left end of the eleventh driving wheel (605) is in transmission connection with a twelfth driving wheel (6012) through a belt; a seventh transmission rod (607) is arranged at the bottom end of the first special-shaped transmission rod (606); a first fixing column (608) is arranged at the left bottom of the seventh transmission rod (607); the left bottom of the seventh transmission rod (607) is connected with a first spring (609), and the inner surface of the first spring (609) is connected with a first fixed column (608); the left part of the front end of the seventh transmission rod (607) is connected with the eighth transmission rod (6010); a first sleeve head (6011) is arranged in the middle of the top end of the eighth transmission rod (6010); the front end axle center of a twelfth driving wheel (6012) is rotatably connected with a second special-shaped driving rod (6013); a ninth transmission rod (6014) is arranged at the bottom end of the second special-shaped transmission rod (6013); a second fixing column (6015) is arranged at the left bottom of the ninth transmission rod (6014); the left bottom of the ninth transmission rod (6014) is connected with a second spring (6016), and the inner surface of the second spring (6016) is connected with a second fixing column (6015); the left part of the front end of the ninth transmission rod (6014) is connected with a tenth transmission rod (6017); a second sleeve head (6018) is arranged in the middle of the top end of the tenth transmission rod (6017); the top end of the ninth driving wheel (601) is connected with a sixth driving wheel (501); the right end axle center of the ninth transmission wheel (601) is connected with the support frame (1) through a mounting seat; the rear end axle center of the tenth transmission wheel (604) is connected with the supporting frame (1) through a mounting seat; the rear end axle center of the eleventh transmission wheel (605) is connected with the supporting frame (1) through a mounting seat; the right part of the rear end of the seventh transmission rod (607) is connected with the support frame (1) through a mounting seat; the bottom end of the first fixing column (608) is connected with the support frame (1); the middle top of the outer surface of the eighth transmission rod (6010) is connected with the support frame (1) through a mounting seat; the rear end axle center of the twelfth transmission wheel (6012) is connected with the support frame (1) through a mounting seat; the right part of the rear end of the ninth transmission rod (6014) is connected with the support frame (1) through a mounting seat; the bottom end of the second fixing column (6015) is connected with the support frame (1); the top of the outer surface of the tenth transmission rod (6017) is connected with the support frame (1) through a mounting seat.

5. A fire-resistant substrate processing apparatus as claimed in claim 4, characterised in that the barbed brush (4026) has a triangular motion trajectory.

6. A fire-resistant substrate processing apparatus as claimed in claim 5, wherein the fifth spur gear (506) is matched with the front middle bump of the profiled sliding plate (507).

7. A fire-proof substrate processing device as claimed in claim 6, characterized in that the first profile driving rod (606) and the seventh driving rod (607) are always in close contact.