CN111923216B - Concrete block processing apparatus - Google Patents

Abstract

The invention relates to a concrete block, in particular to a concrete block processing device. The invention aims to provide a concrete block processing device. The technical implementation scheme of the invention is as follows: a concrete block processing device comprises an operation control screen, a burr processing mechanism, a first impact separation mechanism, a first turnover mechanism, an electric conveying track, a second impact separation mechanism, a second turnover mechanism and the like; welding the first machine tool bottom plate and the second machine tool bottom plate; welding the second machine tool bottom plate and a third machine tool bottom plate; the upper part of the third machine tool bottom plate is connected with the fourth machine tool bottom plate. The invention realizes the deburring operation before the concrete hollow brick is stripped, and the bottom end surface of the concrete hollow brick is separated from the concrete solidification adhesion with the surface of the chopping block, and the deburring treatment effect is respectively carried out on the top end surface and the bottom end surface of the hollow brick through automatic overturning.

Description

Concrete block processing apparatus

Technical Field

The invention relates to a concrete block, in particular to a concrete block processing device.

Background

Concrete blocks are a common building block material in construction and are widely used in modern house construction.

The concrete hollow brick has the characteristics of light weight, fire resistance, sound insulation, heat preservation, permeability resistance, shock resistance, durability and the like, is a green environment-friendly building material which is required by the current generation and has no pollution, energy conservation and consumption reduction, becomes an important component in the new wall material of the current generation, and has wide development space and development prospect.

In prior art, arrange in after the hollow brick drawing of patterns and carry out the natural drying solidification on the chopping block, but because there is the composition of sand and stone in the hollow brick raw materials, and then can not guarantee that the corner is neat after having leaded to its drawing of patterns, the hollow brick can solidify the adhesion with the chopping block after solidifying simultaneously, and then has leaded to there being dry stone that falls scattered in the dry finished product top face of hollow brick, and the precision restriction of mould, cause the hollow brick to have appeared partial concrete deckle edge, build in-process at the building this kind of hollow brick that has the deckle edge and can lead to the wall body slope, dry hollow brick and chopping block adhesion simultaneously, need artifical vibration separation in the take off the board stage, artifical physical demands is huge, the problem of inefficiency.

In view of the above, there is a need to develop a concrete block processing apparatus that overcomes the above problems.

Disclosure of Invention

The invention aims to overcome the defects that because the components of sand and stones exist in the raw materials of a hollow brick, the edges and corners can not be ensured to be tidy after the hollow brick is demoulded, the hollow brick can be solidified and adhered with a chopping block after being solidified, and further, the top end face of a dried finished product of the hollow brick has dried and scattered stones, and the precision of a mould is limited, so that partial concrete burrs appear on the hollow brick, the hollow brick with the burrs can incline a wall body in the building construction process, meanwhile, the dried hollow brick is adhered with the chopping block, manual vibration separation is needed in the plate demoulding stage, the manual labor consumption is huge, and the efficiency is low.

The technical implementation scheme of the invention is as follows: a concrete block processing device comprises a first machine tool bottom plate, a second machine tool bottom plate, a third machine tool bottom plate, a fourth machine tool bottom plate, an operation control screen, a burr processing mechanism, a first impact separation mechanism, a first turnover mechanism, an electric conveying track, a second impact separation mechanism and a second turnover mechanism; welding the first machine tool bottom plate and the second machine tool bottom plate; welding the second machine tool bottom plate and a third machine tool bottom plate; the upper part of the third machine tool bottom plate is connected with a fourth machine tool bottom plate; the upper part of the first machine tool bottom plate is sequentially connected with a second impact separation mechanism and a second turnover mechanism; the upper part of the second machine tool bottom plate is connected with the electric conveying track through bolts; the upper part of the second machine tool bottom plate is connected with the burr treatment mechanism; the upper part of the fourth machine tool bottom plate is sequentially connected with the operation control screen, the burr processing mechanism, the first impact separation mechanism and the first turnover mechanism; the burr processing mechanism is connected with the first impact separation mechanism; the first impact separation mechanism is connected with the first turnover mechanism; the first impact separation mechanism is connected with the electric conveying track; the first impact separation mechanism is connected with the second impact separation mechanism; the first turnover mechanism is connected with the second turnover mechanism;

the burr processing mechanism comprises a first driving wheel, a first bevel gear, a second driving wheel, a first bearing frame plate, a second bearing frame plate, a third driving wheel, a first driving gear, a third bearing frame plate, a fourth bearing frame plate, a second driving gear, a first telescopic rotating shaft, a first bearing sleeve plate, a first rotating shaft rod, a fourth driving wheel, a first electric push rod, a fifth driving wheel, a sixth driving wheel, a seventh driving wheel, a first screw rod, a second screw rod, a fifth bearing frame plate, a sixth bearing frame plate, an eighth driving wheel, a third screw rod, a seventh bearing frame plate, a fourth screw rod, a ninth driving wheel, an eighth bearing frame plate, a third driving gear, a first double-hole internal thread sliding plate, a connecting sliding plate, a second double-hole internal thread sliding groove plate, a downward pressing polishing mechanism and a thirteenth bearing frame plate; the axle center of the first driving wheel is rotationally connected with the first bevel gear; the outer surface of the first bevel gear is sleeved with the first bearing frame plate; the first bevel gear is meshed with the second bevel gear; the second bevel gear core is rotationally connected with a second driving wheel; the axle center of the second driving wheel is inserted with the second bearing frame plate; the outer ring surface of the second driving wheel is in transmission connection with a third driving wheel through a belt; the axle center of the third driving wheel is sequentially connected with the third bearing frame plate and the fourth bearing frame plate; the axle center of the third driving wheel is rotationally connected with the first driving gear; the lower part of the first transmission gear is meshed with the second transmission gear; the axle center of the second transmission gear is rotationally connected with the first telescopic rotating shaft; the outer surface of the first telescopic rotating shaft is connected with the third bearing frame plate; the first telescopic rotor is in rotary connection with the first rotating shaft rod; the first rotating shaft rod is rotationally connected with the fourth driving wheel; the outer surface of the first telescopic rotating shaft is sleeved with the first bearing sleeve plate; the first bearing sleeve plate is inserted with the first electric push rod; the outer surface of the first electric push rod is sequentially connected with the third bearing frame plate and the fourth bearing frame plate; the outer ring surface of the first driving wheel is in transmission connection with a fifth driving wheel through a belt; the axle center of the fifth driving wheel is rotationally connected with the sixth driving wheel; the axis of the sixth transmission wheel is rotationally connected with the second screw rod; the outer ring surface of the sixth driving wheel is in transmission connection with the seventh driving wheel through a belt; the axle center of the seventh transmission wheel is rotationally connected with the first screw rod; the fifth bearing frame plate is sequentially spliced with the first screw rod and the second screw rod; the sixth bearing frame plate is sequentially spliced with the first screw rod and the second screw rod; a third transmission gear is arranged above the second transmission gear; the axle center of the third transmission gear is rotationally connected with the ninth transmission wheel; the outer surface of the third transmission gear is connected with the eighth bearing frame plate; the axis of the ninth transmission wheel is rotationally connected with the fourth screw rod; one side of the fourth screw rod is spliced with the seventh bearing frame plate, and the other side of the fourth screw rod is spliced with the thirteenth bearing frame plate; the outer ring surface of the ninth driving wheel is in transmission connection with the eighth driving wheel through a belt; the axle center of the eighth transmission wheel is rotationally connected with the third screw rod; one side of the third screw rod is spliced with the seventh bearing frame plate, and the other side of the third screw rod is spliced with the thirteenth bearing frame plate; one side inside the first double-hole internal thread sliding plate is sleeved with the fourth screw rod, and the other side inside the first double-hole internal thread sliding plate is sleeved with the third screw rod; the first double-hole internal thread sliding plate is sleeved with the connecting sliding plate; the lower side of the outer surface of the connecting slide bar plate is in sliding connection with a second double-hole internal thread slide groove plate; one side of the interior of the second double-hole internal thread sliding chute plate is sleeved with the first screw rod, and the other side of the second double-hole internal thread sliding chute plate is sleeved with the second screw rod; the lower part of the connecting slide bar plate is inserted into the downward pressing polishing mechanism; the lower parts of the fifth bearing frame plate, the sixth bearing frame plate, the seventh bearing frame plate, the eighth bearing frame plate and the thirteenth bearing frame plate are connected with a second machine tool bottom plate; the lower parts of the first bearing frame plate, the second bearing frame plate, the third bearing frame plate and the fourth bearing frame plate are all connected with a fourth machine tool bottom plate; the fourth driving wheel is connected with the first impact separation mechanism;

the first impact separation mechanism comprises a first power motor, a tenth driving wheel, an eleventh double-track driving wheel, a twelfth double-track driving wheel, a thirteenth double-track driving wheel, a fifth screw rod, a ninth bearing frame plate, a sixth screw rod, a third double-hole internal thread sliding plate, a tenth bearing frame plate, a fourteenth driving wheel, a fifteenth driving wheel, a sixteenth driving wheel, an eleventh bearing frame plate, a seventeenth driving wheel, a first limit chute shell plate, a limit sliding block, a first linking insertion block, a second linking insertion block, a climbing roller, a climbing inclined plate, a first aggregation plate, a first elastic telescopic rod, an impact plate block, a bottom limit sliding strip, a second electric push rod, a clamping push seat and a flushing nozzle; an output shaft of the first power motor is rotationally connected with the tenth transmission wheel; the axle center of the tenth driving wheel is rotationally connected with the eleventh double-track driving wheel; the outer ring surface of the axle center of the tenth driving wheel is in transmission connection with the twelfth double-track driving wheel through a belt; the outer ring surface of the twelfth double-track driving wheel is in transmission connection with the thirteenth double-track driving wheel through a belt; the axis of the twelfth double-track driving wheel is rotationally connected with the sixth screw rod; the axle center of the thirteenth double-track driving wheel is rotationally connected with the fifth screw rod; the ninth bearing frame plate is sequentially sleeved with the fifth screw rod and the sixth screw rod; the third double-hole internal thread sliding plate is sequentially in sliding connection with the fifth screw rod and the sixth screw rod; the tenth bearing frame plate is sequentially sleeved with the fifth screw rod and the sixth screw rod; the outer ring surface of the thirteenth double-track driving wheel is in transmission connection with the fourteenth driving wheel through a belt; the shaft center of the fourteenth driving wheel is sequentially and rotatably connected with the fifteenth driving wheel and the sixteenth driving wheel; the shaft center of the sixteenth driving wheel is inserted with the eleventh bearing frame plate; the outer ring surface of the sixteenth driving wheel is in transmission connection with the seventeenth driving wheel through a belt; the shaft center of the seventeenth transmission wheel is inserted with the eleventh bearing frame plate; the third double-hole internal thread sliding plate is welded with the first limiting chute shell plate; the inner side of the first limiting chute shell plate is in sliding connection with a limiting sliding block; the lower part of the limiting sliding block is sequentially spliced with the first linking insertion block and the second linking insertion block; the lower part of the second connecting inserting block is connected with the climbing roller; a climbing inclined plate is arranged below the climbing roller; the climbing inclined plate is connected with the first collecting plate; the first gathering plate is spliced with the first elastic telescopic rod; the first connecting and inserting block is inserted with the impact plate; the lower part of the impact plate is connected with a bottom limiting slide bar in a sliding way; a second electric push rod and a flushing sprayer are sequentially arranged below the bottom limiting sliding strip; the second electric push rod is connected with the clamping push seat; the lower parts of the ninth bearing frame plate, the tenth bearing frame plate and the eleventh bearing frame plate are connected with a fourth machine tool bottom plate; the eleventh double-track driving wheel is connected with the fourth driving wheel; the eleventh double-track driving wheel is connected with the first turnover mechanism; the lower part of the first power motor is connected with a fourth machine tool bottom plate; the shaft center of the seventeenth driving wheel is connected with the second impact separation mechanism;

the first turnover mechanism comprises a second power motor, a motor fixing seat, an eighteenth driving wheel, a nineteenth driving wheel, a seventh lead screw, a fourth internal thread sliding plate, a first connecting plate, a fixed pulley block, a first collecting column, a second collecting column, a stay cord winding electric shaft column, a twelfth bearing frame plate, a twentieth driving wheel, a second rotating shaft rod, a fourth driving gear, a fifth driving gear, a collecting control disc, a connecting double frame plate, a third electric push rod, a clamping plate and a weighing hook; an output shaft of the second power motor is rotationally connected with the eighteenth driving wheel; the lower part of the second power motor is connected with a motor fixing seat through a bolt; the outer ring surface of the eighteenth driving wheel is in transmission connection with the nineteenth driving wheel through a belt; one side of the axle center of the nineteenth driving wheel is rotatably connected with the seventh screw rod, and the other side of the axle center of the nineteenth driving wheel is spliced with the first connecting plate; a fixed pulley block is arranged above the first connecting plate; the first connecting plate is welded with the first collecting column; the upper part of the first collecting column is connected with a fixed pulley block; the first collecting column is spliced with the second collecting column; a pull rope wound electric shaft column is arranged above the second collecting column; the outer surface of the seventh screw rod is in sliding connection with the fourth internal thread sliding plate; a weighing hook is arranged above the fourth internal thread sliding plate; the lower part of the fourth internal thread sliding plate is spliced with the connecting double-frame plate; the double frame plates are connected with the third electric push rod for splicing; one side of the third electric push rod is inserted into the clamping plate, and the other side of the third electric push rod is connected with the integrated control disc; the axis of the integrated control disc is rotationally connected with a fifth transmission gear; the fifth transmission gear is meshed with the fourth transmission gear; the axle center of the fourth transmission gear is inserted with the second rotating shaft rod; the second rotating shaft rod is rotationally connected with the twentieth driving wheel; the second rotating shaft rod is sleeved with the twelfth bearing frame plate; the lower parts of the motor fixing seat, the twelfth bearing frame plate, the first collecting column and the second collecting column are all connected with a fourth machine tool bottom plate; the twentieth driving wheel is connected with the eleventh double-track driving wheel; the fourth internal thread sliding plate and the second rotating shaft rod are connected with the second turnover mechanism;

the downward pressing polishing mechanism comprises a second assembling plate, a fourth electric push rod, a third assembling plate, a fixed sleeve column and a polishing disc; the lower part of the second gathering plate is spliced with a fourth electric push rod; the lower part of the fourth electric push rod is spliced with the third collecting plate; the third collecting plate is sleeved with the fixed sleeve column; the lower part of the fixed sleeve column is spliced with the polishing disc; the upper part of the second collection plate is connected with the connecting slide plate.

Furthermore, it is particularly preferred that the internal components of the first impact separation device form a symmetrical device, and that the first impact separation device and the second impact separation device form a symmetrical device.

Furthermore, it is particularly preferred that the first and second turning mechanism form a symmetrical mechanism.

In addition, it is particularly preferred that a limiting hollow insert is arranged below the impact plate, the limiting hollow insert is welded to the first limiting sliding groove shell plate above the limiting hollow insert, and the first connecting insert is sequentially inserted into the impact plate and inserted into the limiting hollow insert.

In addition, it is particularly preferred that two infrared sensors are arranged above the second machine tool floor on the side close to the first and second tilting mechanisms.

The beneficial effects are that: the problems that due to the fact that components of sand and stones exist in raw materials of the hollow brick, the corner cannot be guaranteed to be neat after demoulding, the hollow brick can be solidified and adhered to a chopping block after solidification, dry scattered stones exist on the top end face of a dried finished product of the hollow brick, accuracy of a mould is limited, partial concrete burrs occur on the hollow brick, the hollow brick with the burrs can incline a wall body in the building process, the dry hollow brick is adhered to the chopping block, manual vibration separation is needed in the plate demoulding stage, labor power consumption is large, and efficiency is low are solved;

the rough edge processing mechanism, the first impact separation mechanism and the first turnover mechanism are designed, when the concrete hollow brick grinding machine is used, concrete rough edges on the surface above a hollow brick are ground and removed by the rough edge processing mechanism, then the hollow brick is sequentially impacted by the second impact separation mechanism and the first impact separation mechanism, the bottom end face of the hollow brick is separated from a chopping board, then the concrete hollow brick is driven by the first turnover mechanism and the second turnover mechanism to turn over, and then rough edges on the bottom end face of the concrete hollow brick are ground again below the first impact separation mechanism and the second impact separation mechanism;

the unhairing limit operation before having realized taking off the board to the concrete air brick to make concrete air brick bottom face break away from and the chopping block surperficial concrete solidification adhesion, and carry out the effect of unhairing limit processing respectively to hollow brick top face and bottom face through automatic upset.

Drawings

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

FIG. 2 is a schematic perspective view of a burr processing mechanism according to the present invention;

FIG. 3 is a first perspective view of the first impact release mechanism of the present invention;

FIG. 4 is a second perspective view of the first impact release mechanism of the present invention;

FIG. 5 is a schematic view of a first three-dimensional structure of the first turnover mechanism of the present invention;

FIG. 6 is a schematic view of a second three-dimensional structure of the first turnover mechanism of the present invention;

fig. 7 is a schematic perspective view of a down-pressure polishing mechanism according to the present invention.

In the figure: 1. a first machine tool bottom plate, 2, a second machine tool bottom plate, 3, a third machine tool bottom plate, 4, a fourth machine tool bottom plate, 5, an operation control screen, 6, a burr processing mechanism, 7, a first impact separation mechanism, 8, a first turnover mechanism, 9, an electric conveying track, 10, a second impact separation mechanism, 11, a second turnover mechanism, 601, a first transmission wheel, 602, a first bevel gear, 603, a second bevel gear, 604, a second transmission wheel, 605, a first bearing frame plate, 606, a second bearing frame plate, 607, a third transmission wheel, 608, a first transmission gear, 609, a third bearing frame plate, 0, a fourth bearing frame plate, 6011, a second transmission gear, 6012, a first telescopic rotating shaft, 6013, a first bearing sleeve plate, 6014, a first rotating shaft lever, 6015, a fourth transmission wheel, 6016, a first electric push rod, 6017, a fifth transmission wheel, 6018, a sixth transmission wheel, 6019, A seventh driving wheel 6020, a first screw rod 6021, a second screw rod 6022, a fifth bearing frame plate 6023, a sixth bearing frame plate 6024, an eighth driving wheel 6025, a third screw rod 6026, a seventh bearing frame plate 6027, a fourth screw rod 6028, a ninth driving wheel 6029, an eighth bearing frame plate 6030, a third driving gear 6031, a first double-hole internal thread sliding plate 6032, a connecting sliding plate 6033, a second double-hole internal thread sliding groove plate 6034, a down-pressing polishing mechanism 6035, a thirteenth bearing frame plate 701, a first power motor 702, a tenth driving wheel 703, an eleventh double-track driving wheel 704, a twelfth double-track driving wheel 705, a thirteenth double-track driving wheel, a 706, a fifth screw rod 707, a ninth bearing frame plate 708, a sixth screw rod, 709, a third double-hole internal thread sliding plate 7010, a tenth bearing frame plate 7011, a fourteenth driving wheel 7012 and a fifteenth driving wheel, 7013. a sixteenth driving wheel, 7014, an eleventh bearing frame plate, 7015, a seventeenth driving wheel, 7016, a first limit chute shell plate, 7017, a limit sliding block, 7018, a first engaging insertion block, 7019, a second engaging insertion block, 7020, a climbing roller, 7021, a climbing inclined plate, 7022, a first gathering plate, 7023, a first elastic telescopic rod, 7024, an impact plate, 7025, a bottom limit sliding strip, 7026, a second electric push rod, 7027, a clamping push seat, 7028, a flushing nozzle, 801, a second power motor, 802, a motor fixing seat, 803, an eighteenth driving wheel, 804, a nineteenth driving wheel, 805, a seventh lead screw, 806, a fourth internal thread sliding plate, 807, a first engaging plate, 808, a fixed pulley block, 809, a first gathering column, 8010, a second gathering column, 8011, a winding electric shaft column, 8012, a twelfth bearing frame plate, 8013, a twenty-second driving wheel, 8014, a second rotating shaft rod, 8015. a fourth transmission gear 8016, a fifth transmission gear 8017, an integrated control disc 8018, a jointed double-frame plate 8019, a third electric push rod 8020, a clamping plate 8021, a weighing hook 603401, a second integrated plate 603402, a fourth electric push rod 603403, a third integrated plate 603404, a fixed sleeve column 603405 and a polishing disc.

Detailed Description

Embodiments of the present invention will be described in detail below with reference to the accompanying drawings.

Example 1

A concrete block processing device is shown in figures 1-7 and comprises a first machine tool bottom plate 1, a second machine tool bottom plate 2, a third machine tool bottom plate 3, a fourth machine tool bottom plate 4, an operation control screen 5, a burr processing mechanism 6, a first impact separation mechanism 7, a first turnover mechanism 8, an electric conveying track 9, a second impact separation mechanism 10 and a second turnover mechanism 11; welding a first machine tool bottom plate 1 and a second machine tool bottom plate 2; the second machine tool bottom plate 2 is welded with the third machine tool bottom plate 3; the upper part of the third machine tool bottom plate 3 is connected with a fourth machine tool bottom plate 4; the upper part of the first machine tool bottom plate 1 is sequentially connected with a second impact separation mechanism 10 and a second turnover mechanism 11; the upper part of the second machine tool bottom plate 2 is connected with an electric conveying track 9 through bolts; the upper part of the second machine tool bottom plate 2 is connected with a burr processing mechanism 6; the upper part of a fourth machine tool bottom plate 4 is sequentially connected with an operation control screen 5, a burr processing mechanism 6, a first impact separation mechanism 7 and a first turnover mechanism 8; the burr processing mechanism 6 is connected with the first impact separation mechanism 7; the first impact separation mechanism 7 is connected with the first turnover mechanism 8; the first impact separation mechanism 7 is connected with the electric conveying track 9; the first impact separation mechanism 7 is connected with the second impact separation mechanism 10; the first turnover mechanism 8 is connected with the second turnover mechanism 11.

When the concrete block processing device is used, the device is stably fixed to a working plane, then a power supply is connected externally, the operation control screen 5 is manually opened to control the power system in the device to be connected, the solidified concrete hollow brick is conveyed to the lower part of the burr processing mechanism 6 through the electric conveying track 9, then the burr processing mechanism 6 polishes and removes concrete burrs on the upper surface of the hollow brick, then the electric conveying track 9 conveys the concrete hollow brick to the lower parts of the first impact separation mechanism 7 and the second impact separation mechanism 10, then the second impact separation mechanism 10 and the first impact separation mechanism 7 sequentially impact the hollow brick to separate the bottom end surface of the hollow brick from a cutting board, then the electric conveying track 9 conveys the concrete hollow brick to the lower parts of the first turnover mechanism 8 and the second turnover mechanism 11, then the first turnover mechanism 8 and the second turnover mechanism 11 drive the concrete hollow brick to turn over, then electronic transfer rail 9 transports the concrete air brick to first impact separating mechanism 7 and second impact separating mechanism 10 below once more, polishes the bottom face deckle edge of concrete air brick, has realized taking off the deckle edge operation before the board to the concrete air brick to make concrete air brick bottom face break away from and the concrete on chopping block surface solidifies the adhesion, and carries out the effect of deckle edge processing respectively to air brick top face and bottom face through automatic upset.

The burr processing mechanism 6 comprises a first transmission wheel 601, a first bevel gear 602, a second bevel gear 603, a second transmission wheel 604, a first bearing frame plate 605, a second bearing frame plate 606, a third transmission wheel 607, a first transmission gear 608, a third bearing frame plate 609, a fourth bearing frame plate 6010, a second transmission gear 6011, a first telescopic rotating shaft 6012, a first bearing sleeve plate 6013, a first rotating shaft 6014, a fourth transmission wheel 6015, a first electric push rod 6016, a fifth transmission wheel 6017, a sixth transmission wheel 6018, a seventh transmission wheel 6019, a first screw rod 6020, a second screw rod 6021, a fifth bearing frame plate 6022, a sixth bearing frame plate 6023, an eighth transmission wheel 6024, a third screw rod 6025, a seventh bearing frame plate 6026, a fourth screw rod 6027, a ninth transmission wheel 6028, an eighth bearing frame plate 6029, a third transmission gear 6030, a first double-hole internal thread sliding plate 6031, a connecting sliding plate 32, a second double-thread sliding groove 6033 plate 6033, A down-pressure grinding mechanism 6034 and a thirteenth bearing frame plate 6035; the axle center of the first driving wheel 601 is rotationally connected with the first bevel gear 602; the outer surface of the first bevel gear 602 is sleeved with a first bearing frame plate 605; the first bevel gear 602 meshes with the second bevel gear 603; the axle center of the second bevel gear 603 is rotationally connected with a second transmission wheel 604; the axle center of the second driving wheel 604 is inserted with the second bearing frame plate 606; the outer annular surface of the second transmission wheel 604 is in transmission connection with a third transmission wheel 607 through a belt; the axle center of the third transmission wheel 607 is sequentially connected with a third bearing frame plate 609 and a fourth bearing frame plate 6010; the axle center of the third transmission wheel 607 is rotationally connected with the first transmission gear 608; the lower part of the first transmission gear 608 is meshed with a second transmission gear 6011; the axle center of the second transmission gear 6011 is rotationally connected with the first telescopic rotating shaft 6012; the outer surface of the first telescopic rotating shaft 6012 is connected with a third bearing frame plate 609; the first telescopic rotor is rotatably connected with the first spindle rod 6014; the first rotating shaft rod 6014 is rotatably connected with a fourth driving wheel 6015; the outer surface of the first telescopic rotating shaft 6012 is sleeved with a first bearing sleeve plate 6013; the first bearing sleeve plate 6013 is inserted into the first electric push rod 6016; the outer surface of the first electric push rod 6016 is sequentially connected with a third bearing frame plate 609 and a fourth bearing frame plate 6010; the outer ring surface of the first driving wheel 601 is in driving connection with a fifth driving wheel 6017 through a belt; the axle center of the fifth driving wheel 6017 is rotationally connected with a sixth driving wheel 6018; the axis of the sixth driving wheel 6018 is rotatably connected with the second screw rod 6021; the outer ring surface of the sixth driving wheel 6018 is in transmission connection with a seventh driving wheel 6019 through a belt; the axle center of the seventh driving wheel 6019 is rotatably connected with the first screw rod 6020; the fifth bearing frame plate 6022 is sequentially spliced with the first screw rod 6020 and the second screw rod 6021; the sixth bearing frame plate 6023 is sequentially spliced with the first screw rod 6020 and the second screw rod 6021; a third transmission gear 6030 is arranged above the second transmission gear 6011; the axle center of the third transmission gear 6030 is rotationally connected with a ninth driving wheel 6028; the outer surface of the third transmission gear 6030 is connected with an eighth bearing frame plate 6029; the axle center of the ninth driving wheel 6028 is rotatably connected with the fourth screw rod 6027; one side of the fourth screw rod 6027 is spliced with the seventh bearing frame plate 6026, and the other side of the fourth screw rod 6027 is spliced with the thirteenth bearing frame plate 6035; the outer ring surface of the ninth driving wheel 6028 is in transmission connection with the eighth driving wheel 6024 through a belt; the axle center of the eighth driving wheel 6024 is rotatably connected with the third screw rod 6025; one side of the third screw rod 6025 is spliced with the seventh bearing frame plate 6026, and the other side of the third screw rod 6025 is spliced with the thirteenth bearing frame plate 6035; one side inside the first double-hole internal thread sliding plate 6031 is sleeved with the fourth screw rod 6027, and the other side inside the first double-hole internal thread sliding plate 6031 is sleeved with the third screw rod 6025; the first double-hole internal thread sliding plate 6031 is sleeved with a connecting sliding strip plate 6032; the lower side of the outer surface of the connecting slide bar plate 6032 is in sliding connection with a second double-hole internal thread chute plate 6033; one side of the inside of the second dual-hole internal thread chute plate 6033 is sleeved with the first screw rod 6020, and the other side of the second dual-hole internal thread chute plate 6033 is sleeved with the second screw rod 6021; the lower part of the connecting slide bar plate 6032 is spliced with a downward pressing polishing mechanism 6034; the lower parts of a fifth bearing frame plate 6022, a sixth bearing frame plate 6023, a seventh bearing frame plate 6026, an eighth bearing frame plate 6029 and a thirteenth bearing frame plate 6035 are all connected with the second machine tool bottom plate 2; the lower parts of the first bearing frame plate 605, the second bearing frame plate 606, the third bearing frame plate 609 and the fourth bearing frame plate 6010 are all connected with a fourth machine tool bottom plate 4; the fourth transmission wheel 6015 is connected to the first impact separation mechanism 7.

Firstly, conveying the solidified concrete hollow brick to the lower part of a burr treatment mechanism 6 through an electric conveying track 9, simultaneously driving a fourth driving wheel 6015 to rotate by an eleventh double-track driving wheel 703, driving a second driving gear 6011 to rotate by the fourth driving wheel 6015 through a first rotating shaft 6014 and a first telescopic rotating shaft 6012, driving a first driving gear 608 to rotate by the second driving gear 6011, driving a third driving gear 608 to rotate by the first driving gear 608, driving a third driving wheel 607 to rotate by the third driving wheel 607, driving a second driving wheel 604 to rotate, driving a second bevel gear 603 to rotate by the second driving wheel 604, driving a first bevel gear 602 to rotate by the second bevel gear 603, driving a first driving wheel 601 to rotate by the first bevel gear 602, driving a fifth driving wheel 6017 to rotate by the first driving wheel 601, driving a sixth driving wheel 6018 by the fifth driving wheel 6017 to rotate by the seventh driving wheel 6019, then a seventh driving wheel 6019 drives a first screw rod 6020 to rotate, a sixth driving wheel 6018 drives a second screw rod 6021 to rotate, the first screw rod 6020 and the second screw rod 6021 rotate simultaneously to drive a second double-hole internal thread chute plate 6033 to move on the surfaces of the first screw rod 6020 and the second screw rod 6021, a polishing mechanism 6034 is pressed downwards to contact with the top end surface of the hollow brick, the top end surface of the hollow brick is polished, after the polishing mechanism 6034 is pressed downwards to move and polish back and forth, longitudinal polishing is finished, then a first electric push rod 6016 is controlled to push out a first telescopic rotating shaft 6012 driven by a first bearing sleeve plate 6013 to extend, namely the first telescopic rotating shaft 6012 drives a second driving gear 6011 to move to a position meshed with a third driving gear 6030, the third driving gear 6030 drives a ninth driving wheel 6028 to rotate, the ninth driving wheel 6028 drives a fourth screw rod 6027 to rotate, and simultaneously, the ninth driving wheel 6028 drives an eighth driving wheel 6024 to rotate, then the eighth driving wheel 6024 drives the third screw rod 6025 to rotate, and then the third screw rod 6025 and the fourth screw rod 6027 rotate to drive the first double-hole internal thread sliding plate 6031 to move on the surfaces of the third screw rod 6025 and the fourth screw rod 6027, and then the first double-hole internal thread sliding plate 6031 drives the down-pressing polishing mechanism 6034 to move transversely through the connecting sliding plate 6032, namely, the down-pressing polishing mechanism 6034 is controlled to change the position transversely, and then the longitudinal back and forth polishing is carried out again until the top end face of the hollow brick is completely polished, and the polishing of the burrs of the top end face of the hollow brick is completed.

The first impact separation mechanism 7 comprises a first power motor 701, a tenth driving wheel 702, an eleventh double-track driving wheel 703, a twelfth double-track driving wheel 704, a thirteenth double-track driving wheel 705, a fifth screw rod 706, a ninth bearing frame plate 707, a sixth screw rod 708, a third double-hole internal thread sliding plate 709, a tenth bearing frame plate 7010, a fourteenth driving wheel 7011, a fifteenth driving wheel 7012, a sixteenth driving wheel 7013, an eleventh bearing frame plate 7014, a seventeenth driving wheel 7015, a first limit sliding chute shell plate 7016, a limit sliding block 7017, a first connection insertion block 7018, a second connection insertion block 7019, a climbing roller 7020, a climbing inclined plate 7021, a first collection plate 7022, a first elastic telescopic rod 7023, an impact plate 7024, a bottom limit sliding strip 7025, a second electric push rod 7026, a clamping push seat 7027 and a flushing sprayer 7028; an output shaft of the first power motor 701 is rotatably connected with a tenth transmission wheel 702; the axle center of the tenth driving wheel 702 is rotationally connected with the eleventh double-track driving wheel 703; the outer ring surface of the axle center of the tenth driving wheel 702 is in driving connection with a twelfth double-track driving wheel 704 through a belt; the outer annular surface of the twelfth double-track driving wheel 704 is in transmission connection with a thirteenth double-track driving wheel 705 through a belt; the axle center of the twelfth double-track driving wheel 704 is rotationally connected with the sixth screw rod 708; the axle center of the thirteenth double-track driving wheel 705 is rotationally connected with the fifth screw rod 706; a ninth bearing frame plate 707 is sequentially sleeved with a fifth screw rod 706 and a sixth screw rod 708; the third double-hole internal thread sliding plate 709 is sequentially in sliding connection with the fifth screw rod 706 and the sixth screw rod 708; the tenth bearing frame plate 7010 is sequentially sleeved with the fifth screw rod 706 and the sixth screw rod 708; the outer ring surface of the thirteenth double-track driving wheel 705 is in transmission connection with a fourteenth driving wheel 7011 through a belt; the axle center of the fourteenth driving wheel 7011 is sequentially in rotary connection with the fifteenth driving wheel 7012 and the sixteenth driving wheel 7013; the axle center of the sixteenth driving wheel 7013 is spliced with the eleventh bearing frame plate 7014; the outer ring surface of the sixteenth driving wheel 7013 is in transmission connection with a seventeenth driving wheel 7015 through a belt; the axle center of the seventeenth driving wheel 7015 is spliced with the eleventh bearing frame plate 7014; the third double-hole internal thread sliding plate 709 is welded with the first limiting sliding chute shell plate 7016; the inner side of the first limit chute shell plate 7016 is in sliding connection with a limit sliding block 7017; the lower part of the limit sliding block 7017 is sequentially spliced with a first splicing insertion block 7018 and a second splicing insertion block 7019; the lower part of the second connecting plug 7019 is connected with a climbing roller 7020; a climbing inclined plate 7021 is arranged below the climbing roller 7020; the climbing sloping plate 7021 is connected with the first collecting plate 7022; the first gathering plate 7022 is spliced with the first elastic telescopic rod 7023; the first engagement plug 7018 is inserted into the impact plate 7024; the lower part of the impact plate 7024 is in sliding connection with a bottom limiting sliding strip 7025; a second electric push rod 7026 and a flushing sprayer 7028 are sequentially arranged below the bottom limiting sliding strip 7025; the second electric push rod 7026 is connected with the clamping push seat 7027; the lower parts of the ninth bearing frame plate 707, the tenth bearing frame plate 7010 and the eleventh bearing frame plate 7014 are all connected with the fourth machine tool bottom plate 4; the eleventh double-track driving wheel 703 is connected with a fourth driving wheel 6015; the eleventh double-track driving wheel 703 is connected with the first turnover mechanism 8; the lower part of the first power motor 701 is connected with a fourth machine tool bottom plate 4; the axis of the seventeenth driving wheel 7015 is connected with the second impact separation mechanism 10.

The electric conveying track 9 conveys the concrete hollow brick to the lower part of the first impact separation mechanism 7 and the second impact separation mechanism 10, then the power supply of the first power motor 701 is controlled to be switched on by the operation control screen 5, then the first power motor 701 drives the tenth driving wheel 702 and the eleventh double-track driving wheel 703 to rotate, then the twelfth driving wheel 702 drives the twelfth double-track driving wheel 704 to rotate, then the twelfth double-track driving wheel 704 drives the thirteenth double-track driving wheel 705 to rotate, then the thirteenth double-track driving wheel 705 drives the fifth double-track screw 706 to rotate, at the same time the twelfth driving wheel 704 drives the sixth screw 708 to rotate, then the fifth screw 706 and the sixth screw 708 drive the third double-hole internal thread sliding plate 709 to move towards the direction close to the ninth bearing frame plate 707, and then the third double-hole internal thread sliding plate 709 drives the limit sliding block 7017 to move, and then the spacing sliding block 7017 drives the impact plate 7024 to move through the first linking insert 7018, and simultaneously the spacing sliding block 7017 drives the climbing roller 7020 to roll on the climbing inclined plate 7021 through the second linking insert 7019 and slowly rises, namely the first linking insert 7018 is driven to be slowly pulled away from the impact plate 7024, when the impact plate 7024 is pulled out by the first linking insert, at the moment, because the first elastic telescopic rod 7023 is compressed, and then the elastic force of the first elastic telescopic rod 7023 drives the impact plate 7024 to impact the hollow brick, before that, the second electric push rod 7026 is controlled to be pushed out to drive the clamping and pushing seat 7027 to clamp and fix the chopping block, then the hollow brick above the chopping block is impacted and separated from the chopping block, and simultaneously the hollow brick can be washed and separated in an auxiliary way by connecting the external water inlet pipe through the washing nozzle 7028.

The first turnover mechanism 8 comprises a second power motor 801, a motor fixing seat 802, an eighteenth driving wheel 803, a nineteenth driving wheel 804, a seventh screw rod 805, a fourth internal thread sliding plate 806, a first connecting plate 807, a fixed pulley block 808, a first gathering column 809, a second gathering column 8010, a stay cord winding electric axle column 8011, a twelfth bearing frame plate 8012, a twentieth driving wheel 8013, a second rotating shaft rod 8014, a fourth driving gear 8015, a fifth driving gear 8016, a gathering control disc 8017, a connecting double frame plate 8018, a third electric push rod 8019, a clamping plate 8020 and a weighing hook 8021; an output shaft of the second power motor 801 is rotatably connected with an eighteenth transmission wheel 803; the lower part of the second power motor 801 is connected with a motor fixing seat 802 through bolts; the outer ring surface of the eighteenth driving wheel 803 is in transmission connection with the nineteenth driving wheel 804 through a belt; one side of the axle center of the nineteenth driving wheel 804 is rotatably connected with the seventh screw 805, and the other side of the axle center of the nineteenth driving wheel 804 is inserted into the first connecting plate 807; a fixed pulley block 808 is arranged above the first connecting plate 807; the first joint plate 807 is welded to the first collecting column 809; the upper part of the first collecting column 809 is connected with a fixed pulley block 808; the first gathering column 809 is spliced with the second gathering column 8010; a pull rope wound electric shaft column 8011 is arranged above the second gathering column 8010; the outer surface of the seventh screw rod 805 is in sliding connection with a fourth internal thread sliding plate 806; a weighing hook 8021 is arranged above the fourth internal thread sliding plate 806; the lower part of the fourth internal thread sliding plate 806 is spliced with a connecting double-frame plate 8018; the connecting double-frame plate 8018 is spliced with the third electric push rod 8019; one side of the third electric push rod 8019 is inserted into the clamping plate 8020, and the other side of the third electric push rod 8019 is connected with the integrated control disc 8017; the axis of the integrated control disc 8017 is rotatably connected with the fifth transmission gear 8016; the fifth transmission gear 8016 is meshed with the fourth transmission gear 8015; the axis of the fourth transmission gear 8015 is inserted into the second rotating shaft 8014; the second rotating shaft rod 8014 is rotatably connected with the twentieth driving wheel 8013; the second rotating shaft rod 8014 is sleeved with the twelfth bearing frame plate 8012; the lower parts of the motor fixing seat 802, the twelfth bearing frame plate 8012, the first gathering column 809 and the second gathering column 8010 are all connected with the fourth machine tool bottom plate 4; the twentieth driving wheel 8013 is connected with the eleventh double-track driving wheel 703; the fourth internal thread sliding plate 806 and the second rotating shaft rod 8014 are connected with the second turnover mechanism 11; .

Firstly, a lifting rope is wound on the outer surface of a stay cord wound electric pivot 8011, one end of the lifting rope is wound on a weighing lifting hook 8021 by winding a fixed pulley block 808, then an electric transfer rail 9 conveys a concrete hollow brick to the lower part of a first turnover mechanism 8 and a second turnover mechanism 11, then a third electric push rod 8019 drives a clamping plate 8020 to push out and cooperate with the second turnover mechanism 11 to clamp the hollow brick, then a second power motor 801 drives an eighteenth driving wheel 803 to rotate so as to drive a nineteenth driving wheel 804 to rotate, then the nineteenth driving wheel 804 drives a seventh lead screw 805 to rotate, meanwhile, the seventh lead screw 805 rotates to drive a fourth internal thread sliding plate 806 to slide upwards, further, a double-frame plate 8018 is connected to drive the third electric push rod 8019, the clamping plate 8020 and the weighing lifting hook 8021 to move upwards, and simultaneously, the stay cord wound electric pivot 8011 drives the lifting rope to move upwards, namely, the weighing lifting hook 8021 is pulled upwards, the hollow brick is clamped and separated from the chopping block, the fifth transmission gear 8016 is driven to move to the position where the fifth transmission gear 8015 is meshed with the fourth transmission gear 8015 through the integrated control disc 8017, the twentieth transmission gear 8013 drives the fourth transmission gear 8015 and further drives the fifth transmission gear 8016 to rotate, the fifth transmission gear 8016 drives the integrated control disc 8017, the connecting double-frame plate 8018, the third electric push rod 8019 and the clamping plate 8020 to rotate to drive the hollow brick to turn, the bottom end face of the hollow brick faces upwards, the turning of the hollow brick is completed, and the bottom end face is polished by burrs.

The downward pressing polishing mechanism 6034 comprises a second assembling plate 603401, a fourth electric push rod 603402, a third assembling plate 603403, a fixed sleeve column 603404 and a polishing disc 603405; the lower part of the second gathering plate 603401 is spliced with a fourth electric push rod 603402; the lower part of the fourth electric push rod 603402 is spliced with a third gathering plate 603403; the third gathering plate 603403 is sleeved with the fixed sleeve column 603404; the lower part of the fixed sleeve column 603404 is spliced with the polishing disc 603405; the second collecting plate 603401 is connected above with a connecting slide plate 6032.

The fourth electric push rod 603402 drives the third gathering plate 603403 and the fixed sleeve column 603404 to move downwards, and then the fixed sleeve column 603404 drives the polishing disc 603405 to be close to and contact with the surface of the hollow brick for polishing.

The internal structural components of the first impact separation mechanism 7 are symmetrical mechanisms, and the first impact separation mechanism 7 and the second impact separation mechanism 10 are symmetrical mechanisms.

So that the two sides of the hollow brick can be operated simultaneously, the balance of operation is ensured, and the hollow brick can not deviate.

The first turnover mechanism 8 and the second turnover mechanism 11 form a symmetrical mechanism.

So that the hollow brick can be clamped in two directions for overturning.

A limit hollow insert block is arranged below the impact plate 7024, the upper part of the limit hollow insert block is welded with a first limit sliding chute shell plate 7016, and a first connecting insert block 7018 is sequentially spliced with the impact plate 7024 and the limit hollow insert block.

So that drive the impact plate 7024 through first linking inserted block 7018 and move, and then drive first elasticity telescopic link 7023 and compress and produce the impact elasticity, and after first linking inserted block 7018 left impact plate 7024, the elasticity of first elasticity telescopic link 7023 drives impact plate 7024 and assaults the hollow brick.

Two infrared sensors are arranged on one side, close to the first turnover mechanism 8 and the second turnover mechanism 11, above the second machine tool bottom plate 2.

So that when the hollow brick is placed above the electric conveying track 9, whether the positions of the chopping block and the hollow brick deviate from the working center line can be judged.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims (5)

1. The utility model provides a concrete block processing apparatus, including first lathe bottom plate (1), second lathe bottom plate (2) and third lathe bottom plate (3), characterized by: the device is characterized by also comprising a fourth machine tool bottom plate (4), an operation control screen (5), a burr processing mechanism (6), a first impact separation mechanism (7), a first turnover mechanism (8), an electric conveying track (9), a second impact separation mechanism (10) and a second turnover mechanism (11); the first machine tool bottom plate (1) and the second machine tool bottom plate (2) are welded; the second machine tool bottom plate (2) is welded with the third machine tool bottom plate (3); the upper part of the third machine tool bottom plate (3) is connected with a fourth machine tool bottom plate (4); the upper part of the first machine tool bottom plate (1) is sequentially connected with a second impact separation mechanism (10) and a second turnover mechanism (11); the upper part of the second machine tool bottom plate (2) is connected with an electric conveying track (9) through bolts; the upper part of the second machine tool bottom plate (2) is connected with a burr treatment mechanism (6); the upper part of a fourth machine tool bottom plate (4) is sequentially connected with an operation control screen (5), a burr processing mechanism (6), a first impact separation mechanism (7) and a first turnover mechanism (8); the burr processing mechanism (6) is connected with the first impact separation mechanism (7); the first impact separation mechanism (7) is connected with the first turnover mechanism (8); the first impact separation mechanism (7) is connected with the electric transmission track (9); the first impact separation mechanism (7) is connected with the second impact separation mechanism (10); the first turnover mechanism (8) is connected with the second turnover mechanism (11);

the burr processing mechanism (6) comprises a first transmission wheel (601), a first bevel gear (602), a second bevel gear (603), a second transmission wheel (604), a first bearing frame plate (605), a second bearing frame plate (606), a third transmission wheel (607), a first transmission gear (608), a third bearing frame plate (609), a fourth bearing frame plate (6010), a second transmission gear (6011), a first telescopic rotating shaft (6012), a first bearing sleeve plate (6013), a first rotating shaft rod (6014), a fourth transmission wheel (6015), a first electric push rod (6016), a fifth transmission wheel (6017), a sixth transmission wheel (6018), a seventh transmission wheel (6019), a first screw rod (6020), a second screw rod (6021), a fifth bearing frame plate (6022), a sixth bearing frame plate (6023), an eighth transmission wheel (6024), a third screw rod (6025), a seventh bearing frame plate (6026), a fourth screw rod (6027), a first bevel gear (6027), a second bevel gear (6022), a third bevel gear (6025), a fourth bevel gear (6026), a third bevel gear (6015), a fourth bevel gear (6010), a fourth bevel gear (6012), a fourth bevel gear (6015), a fourth bevel gear (6012), a fourth bevel gear (6012), a fourth bevel gear, a fourth shaft sleeve plate (6013), a fourth shaft sleeve plate (6012), a fourth shaft sleeve plate (6013), a fourth shaft sleeve plate (6012), a fourth shaft sleeve plate (6015), a fourth shaft sleeve plate (6012), a fourth shaft sleeve plate (6015), a fourth shaft sleeve plate (6013), a fourth shaft sleeve plate (6015), a fourth shaft sleeve (6015), a fourth shaft sleeve, a, A ninth driving wheel (6028), an eighth bearing frame plate (6029), a third driving gear (6030), a first double-hole internal thread sliding plate (6031), a connecting sliding plate (6032), a second double-hole internal thread sliding groove plate (6033), a downward pressing polishing mechanism (6034) and a thirteenth bearing frame plate (6035); the axle center of the first transmission wheel (601) is rotationally connected with the first bevel gear (602); the outer surface of the first bevel gear (602) is sleeved with a first bearing frame plate (605); the first bevel gear (602) is meshed with the second bevel gear (603); the axle center of the second bevel gear (603) is rotationally connected with a second transmission wheel (604); the axle center of the second transmission wheel (604) is spliced with a second bearing frame plate (606); the outer ring surface of the second driving wheel (604) is in transmission connection with a third driving wheel (607) through a belt; the axle center of the third transmission wheel (607) is sequentially connected with a third bearing frame plate (609) and a fourth bearing frame plate (6010); the axle center of the third transmission wheel (607) is rotationally connected with the first transmission gear (608); the lower part of the first transmission gear (608) is meshed with a second transmission gear (6011); the axle center of the second transmission gear (6011) is rotationally connected with the first telescopic rotating shaft (6012); the outer surface of the first telescopic rotating shaft (6012) is connected with a third bearing frame plate (609); the first telescopic rotor is rotationally connected with a first rotating shaft rod (6014); the first rotating shaft rod (6014) is rotationally connected with a fourth driving wheel (6015); the outer surface of the first telescopic rotating shaft (6012) is sleeved with a first bearing sleeve plate (6013); the first bearing sleeve plate (6013) is spliced with a first electric push rod (6016); the outer surface of the first electric push rod (6016) is sequentially connected with a third bearing frame plate (609) and a fourth bearing frame plate (6010); the outer ring surface of the first transmission wheel (601) is in transmission connection with a fifth transmission wheel (6017) through a belt; the axle center of the fifth driving wheel (6017) is rotationally connected with a sixth driving wheel (6018); the axis of a sixth transmission wheel (6018) is rotationally connected with a second screw rod (6021); the outer ring surface of the sixth driving wheel (6018) is in transmission connection with a seventh driving wheel (6019) through a belt; the axle center of a seventh transmission wheel (6019) is rotationally connected with the first screw rod (6020); the fifth bearing frame plate (6022) is sequentially spliced with the first screw rod (6020) and the second screw rod (6021); the sixth bearing frame plate (6023) is sequentially spliced with the first screw rod (6020) and the second screw rod (6021); a third transmission gear (6030) is arranged above the second transmission gear (6011); the axle center of the third transmission gear (6030) is rotationally connected with a ninth transmission wheel (6028); the outer surface of the third transmission gear (6030) is connected with an eighth bearing frame plate (6029); the axle center of the ninth transmission wheel (6028) is rotationally connected with the fourth screw rod (6027); one side of a fourth screw rod (6027) is spliced with a seventh bearing frame plate (6026), and the other side of the fourth screw rod (6027) is spliced with a thirteenth bearing frame plate (6035); the outer ring surface of the ninth driving wheel (6028) is in transmission connection with the eighth driving wheel (6024) through a belt; the axle center of the eighth driving wheel (6024) is rotationally connected with the third screw rod (6025); one side of the third screw rod (6025) is spliced with the seventh bearing frame plate (6026), and the other side of the third screw rod (6025) is spliced with the thirteenth bearing frame plate (6035); one side of the inside of the first double-hole internal thread sliding plate (6031) is sleeved with the fourth screw rod (6027), and the other side of the inside of the first double-hole internal thread sliding plate (6031) is sleeved with the third screw rod (6025); the first double-hole internal thread sliding plate (6031) is sleeved with the connecting sliding plate (6032); the lower side of the outer surface of the connecting slide bar plate (6032) is in sliding connection with a second double-hole internal thread slide groove plate (6033); one side of the inside of the second double-hole internal thread chute plate (6033) is sleeved with the first screw rod (6020), and the other side of the second double-hole internal thread chute plate (6033) is sleeved with the second screw rod (6021); the lower part of the connecting slide bar plate (6032) is spliced with a downward pressing polishing mechanism (6034); the lower parts of a fifth bearing frame plate (6022), a sixth bearing frame plate (6023), a seventh bearing frame plate (6026), an eighth bearing frame plate (6029) and a thirteenth bearing frame plate (6035) are connected with the second machine tool bottom plate (2); the lower parts of the first bearing frame plate (605), the second bearing frame plate (606), the third bearing frame plate (609) and the fourth bearing frame plate (6010) are connected with a fourth machine tool bottom plate (4); the fourth transmission wheel (6015) is connected with the first impact separation mechanism (7);

the first impact separation mechanism (7) comprises a first power motor (701), a tenth driving wheel (702), an eleventh double-track driving wheel (703), a twelfth double-track driving wheel (704), a thirteenth double-track driving wheel (705), a fifth screw rod (706), a ninth bearing frame plate (707), a sixth screw rod (708), a third double-hole internal thread sliding plate (709), a tenth bearing frame plate (7010), a fourteenth driving wheel (7011), a fifteenth driving wheel (7012), a sixteenth driving wheel (7013), an eleventh bearing frame plate (7014), a seventeenth driving wheel (7015), a first limiting sliding groove shell plate (7016), a limiting sliding block (7017), a first connecting insert block (7018), a second connecting insert block (7019), a climbing roller (7020), a climbing inclined plate (7021), a first aggregation plate (7022), a first elastic telescopic rod (7023), an impact plate (7024), a bottom limiting slide bar (7025), a second lifting roller (7020), a climbing roller, a climbing inclined plate (7023), a first impact plate (7024), A second electric push rod (7026), a clamping push seat (7027) and a flushing sprayer (7028); an output shaft of the first power motor (701) is rotationally connected with a tenth transmission wheel (702); the axle center of the tenth driving wheel (702) is rotationally connected with the eleventh double-track driving wheel (703); the outer ring surface of the axle center of the tenth driving wheel (702) is in transmission connection with a twelfth double-track driving wheel (704) through a belt; the outer annular surface of the twelfth double-track driving wheel (704) is in transmission connection with a thirteenth double-track driving wheel (705) through a belt; the axle center of the twelfth double-track driving wheel (704) is rotationally connected with a sixth screw rod (708); the axle center of a thirteenth double-track driving wheel (705) is rotationally connected with a fifth screw rod (706); the ninth bearing frame plate (707) is sequentially sleeved with the fifth screw rod (706) and the sixth screw rod (708); the third double-hole internal thread sliding plate (709) is sequentially in sliding connection with the fifth screw rod (706) and the sixth screw rod (708); the tenth bearing frame plate (7010) is sequentially sleeved with the fifth screw rod (706) and the sixth screw rod (708); the outer ring surface of the thirteenth double-track driving wheel (705) is in transmission connection with a fourteenth driving wheel (7011) through a belt; the axle center of the fourteenth driving wheel (7011) is sequentially and rotatably connected with the fifteenth driving wheel (7012) and the sixteenth driving wheel (7013); the axis of a sixteenth driving wheel (7013) is spliced with an eleventh bearing frame plate (7014); the outer ring surface of the sixteenth driving wheel (7013) is in transmission connection with a seventeenth driving wheel (7015) through a belt; the axis of the seventeenth driving wheel (7015) is spliced with an eleventh bearing frame plate (7014); the third double-hole internal thread sliding plate (709) is welded with the first limiting sliding chute shell plate (7016); the inner side of the first limit chute shell plate (7016) is in sliding connection with a limit sliding block (7017); the lower part of the limit sliding block (7017) is sequentially spliced with a first splicing insertion block (7018) and a second splicing insertion block (7019); the lower part of the second connecting plug block (7019) is connected with a climbing roller (7020); a climbing inclined plate (7021) is arranged below the climbing roller (7020); the climbing inclined plate (7021) is connected with the first gathering plate (7022); the first gathering plate (7022) is spliced with the first elastic telescopic rod (7023); the first connecting plug block (7018) is spliced with the impact plate (7024); the lower part of the impact plate (7024) is in sliding connection with a bottom limiting sliding strip (7025); a second electric push rod (7026) and a flushing sprayer (7028) are sequentially arranged below the bottom limiting sliding strip (7025); the second electric push rod (7026) is connected with the clamping push seat (7027); the lower parts of the ninth bearing frame plate (707), the tenth bearing frame plate (7010) and the eleventh bearing frame plate (7014) are connected with a fourth machine tool bottom plate (4); the eleventh double-track driving wheel (703) is connected with a fourth driving wheel (6015); the eleventh double-track driving wheel (703) is connected with the first turnover mechanism (8); the lower part of the first power motor (701) is connected with a fourth machine tool bottom plate (4); the axle center of a seventeenth driving wheel (7015) is connected with a second impact separation mechanism (10);

the first turnover mechanism (8) comprises a second power motor (801), a motor fixing seat (802), an eighteenth driving wheel (803), a nineteenth driving wheel (804), a seventh screw rod (805), a fourth internal thread sliding plate (806), a first connecting plate (807), a fixed pulley block (808), a first collecting column (809), a second collecting column (8010), a stay cord wound electric shaft column (8011), a twelfth bearing frame plate (8012), a twentieth driving wheel (8013), a second rotating shaft rod (8014), a fourth transmission gear (8015), a fifth transmission gear (8016), a collecting control disc (8017), a connecting double frame plate (8018), a third electric push rod (8019), a clamping plate (8020) and a weighing hook (8021); an output shaft of the second power motor (801) is rotationally connected with an eighteenth transmission wheel (803); the lower part of the second power motor (801) is connected with a motor fixing seat (802) through a bolt; the outer ring surface of the eighteenth driving wheel (803) is in transmission connection with the nineteenth driving wheel (804) through a belt; one side of the axle center of the nineteenth driving wheel (804) is rotatably connected with the seventh screw rod (805), and the other side of the axle center of the nineteenth driving wheel (804) is spliced with the first connecting plate (807); a fixed pulley block (808) is arranged above the first connecting plate (807); the first connecting plate (807) is welded with the first gathering column (809); the upper part of the first collecting column (809) is connected with a fixed pulley block (808); the first collecting column (809) is spliced with the second collecting column (8010); a pull rope winding electric shaft column (8011) is arranged above the second collecting column (8010); the outer surface of the seventh screw rod (805) is in sliding connection with a fourth internal thread sliding plate (806); a weighing hook (8021) is arranged above the fourth internal thread sliding plate (806); the lower part of the fourth internal thread sliding plate (806) is spliced with a connecting double-frame plate (8018); the connecting double frame plates (8018) are spliced with the third electric push rod (8019); one side of the third electric push rod (8019) is inserted into the clamping plate (8020), and the other side of the third electric push rod (8019) is connected with the integrated control disc (8017); the axis of the integrated control disc (8017) is rotationally connected with the fifth transmission gear (8016); the fifth transmission gear (8016) is meshed with the fourth transmission gear (8015); the axis of the fourth transmission gear (8015) is spliced with the second rotating shaft rod (8014); the second rotating shaft rod (8014) is rotationally connected with the twentieth driving wheel (8013); the second rotating shaft rod (8014) is sleeved with the twelfth bearing frame plate (8012); the lower parts of the motor fixing seat (802), the twelfth bearing frame plate (8012), the first collecting column (809) and the second collecting column (8010) are connected with a fourth machine tool bottom plate (4); the twentieth driving wheel (8013) is connected with the eleventh double-track driving wheel (703); the fourth internal thread sliding plate (806) and the second rotating shaft rod (8014) are connected with the second turnover mechanism (11);

the downward pressing polishing mechanism (6034) comprises a second assembling plate (603401), a fourth electric push rod (603402), a third assembling plate (603403), a fixed sleeve column (603404) and a polishing disc (603405); a fourth electric push rod (603402) is inserted below the second gathering plate (603401); the lower part of the fourth electric push rod (603402) is spliced with a third gathering plate (603403); the third gathering plate (603403) is sleeved with the fixed sleeve column (603404); the lower part of the fixed sleeve column (603404) is spliced with the polishing disc (603405); the upper part of the second gathering plate (603401) is connected with a connecting slide plate (6032).

2. A concrete block handling device according to claim 1 wherein: the internal structural components of the first impact separation mechanism (7) are symmetrical mechanisms, and the first impact separation mechanism (7) and the second impact separation mechanism (10) are symmetrical mechanisms.

3. A concrete block handling device according to claim 2 wherein: the first turnover mechanism (8) and the second turnover mechanism (11) form a symmetrical mechanism.

4. A concrete block handling device according to claim 3 wherein: the lower part of the impact plate (7024) is provided with a limiting hollow insert block, the upper part of the limiting hollow insert block is welded with a first limiting sliding groove shell plate (7016), and a first connecting insert block (7018) is sequentially spliced with the impact plate (7024) and spliced with the limiting hollow insert block.

5. A concrete block handling device according to claim 4 wherein: two infrared sensors are arranged on one side, close to the first turnover mechanism (8) and the second turnover mechanism (11), above the second machine tool bottom plate (2).

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