CN111844462A

CN111844462A - Granite ore processing device

Info

Publication number: CN111844462A
Application number: CN202010773215.2A
Authority: CN
Inventors: 卢昌敏
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-08-04
Filing date: 2020-08-04
Publication date: 2020-10-30

Abstract

The invention relates to the field of ores, in particular to a granite ore processing device. The invention aims to provide a granite ore processing device. A granite ore processing device comprises a machine tool collecting plate, a clamping movement control mechanism, a first shifting and reversing mechanism, a closed cutting mechanism, a stone powder processing mechanism, a second shifting and reversing mechanism, a three-leg chassis and the like; and the lower part of the machine tool assembly plate is welded with the three-leg chassis. According to the invention, granite ore is automatically clamped and fixed, meanwhile, the problem that the health of a human body is influenced because mountain flour is dissociated into air and sucked by the human body is solved by adopting a closed cutting mode, meanwhile, aiming at multi-surface cutting of the granite ore, an automatic ore overturning mode is adopted, and meanwhile, the iron removal operation is carried out on the granite ore powder with higher iron content, so that the effect of pure granite ore powder which can be used for subsequent processing is obtained.

Description

Granite ore processing device

Technical Field

The invention relates to the field of ores, in particular to a granite ore processing device.

Background

Granite is a structural rock formed by the molten lava erupting from volcano under a certain pressure and rising to the surface of the earth crust, the magma is not sprayed out of the ground, but is slowly cooled and solidified in the ground, and the granite is a deep acidic igneous rock and belongs to magma rock. Granite comprises quartz, feldspar and mica as main components. Wherein the feldspar content is 40% -60%, the quartz content is 20% -40%, and the color is determined by the types and the amount of the contained components.

Before granite is processed, granite with an irregular shape is often cut into a regular shape, namely, granite stone is cut into granite stone, but in the prior art, the shape of the granite is not uniform enough, a uniform cutting instrument cannot be adopted to automatically cut the granite, the granite is manually cut and chiseled in a matched mode in the processing process of the granite stone, a large amount of stone powder can be generated in the cutting process, the iron content of the granite stone powder is high, the stone powder generated by cutting in the manual cutting process floats in the air, even if protective measures are manually taken, the particle size of the stone powder is small, part of the stone powder can enter a human body through a respiratory tract, and further, when the granite is manually chiseled, the broken shape of the granite cannot be controlled, the section of the granite stone is uneven, and meanwhile, when the cutting is manually controlled, the stone powder floats to suck in a lung for a long time, so that a lung disease is caused, meanwhile, the stone powder with high iron content can not be applied subsequently due to the existence of iron, and the stone powder enters the nature to influence the growth of animals and plants and destroy the ecological environment.

In view of the above, there is a need to develop a granite ore processing apparatus to overcome the above problems.

Disclosure of Invention

The invention aims to overcome the defects that in the prior art, the granite has a non-uniform shape and cannot be automatically cut by adopting a uniform cutting instrument, the granite is manually cut and chiseled in a matched mode in the process of processing the granite, a large amount of stone powder is generated in the cutting process, the iron content of the granite stone powder is high, the stone powder generated by cutting in the manual cutting process floats in the air, even if protective measures are manually taken, the particle size of the stone powder is small, part of the stone powder enters a human body through a respiratory tract, and further, when the granite is manually chiseled, the broken shape of the granite cannot be controlled, the uneven section of the granite can be caused, and meanwhile, when the cutting is manually controlled, the stone powder floats for a long time and is sucked to cause lung diseases, namely pneumoconiosis, and the stone powder with high iron content can not be subsequently applied due to the existence of iron, the invention aims to solve the technical problem of providing a granite ore processing device.

The invention is achieved by the following specific technical means:

a granite ore processing device comprises a machine tool collecting plate, a first side machine tool plate, an elevating platform column, a real-time control screen, a long-distance transmission electric slide rail, a clamping movement control mechanism, a first shifting reversing mechanism, a closed cutting mechanism, a stone powder processing mechanism, a second shifting reversing mechanism and a three-leg chassis; welding the lower part of the machine tool assembly plate with the three-leg chassis; welding a machine tool assembly plate with a first side machine tool plate; one side of the machine tool assembly plate is connected with the first shifting and reversing mechanism, and the other side of the machine tool assembly plate is connected with the second shifting and reversing mechanism; the upper part of the machine tool assembly plate is connected with a long-distance transmission electric slide rail; the upper part of the first side machine bed plate is welded with the overhead table column; the elevating platform column is connected with the real-time control screen; the upper part of the elevated platform column is connected with the stone powder treatment mechanism; the stone powder treatment mechanism is connected with the closed cutting mechanism; the lower part of the closed cutting mechanism is sequentially connected with a machine tool assembling plate and a first side machine tool plate; the upper part of the long-distance transmission electric slide rail is connected with a clamping movement control mechanism.

Further, the clamping and moving control mechanism comprises a servo motor, a first gathering plate, a first lead screw, a first internal thread sliding block, a first rectangular chute plate, a second internal thread sliding block, a first bearing plate, a first connecting plate, a first driving wheel, a first elastic steel bar fixing grate, a second driving wheel, a second bearing plate, a second connecting plate, a second lead screw, a third internal thread sliding block, a second rectangular chute plate, a fourth internal thread sliding block, a third bearing plate and a third connecting plate; an output shaft of the servo motor is rotationally connected with the first screw rod; the lower part of the servo motor is sleeved with the first collecting plate; the outer surface of the first screw rod is sequentially sleeved with a first internal thread sliding block, a second internal thread sliding block and a first bearing plate; the first internal thread sliding block is connected with the first elastic steel bar fixing grate; one side of the first rectangular sliding groove plate is spliced with the first gathering plate, and the other side of the first rectangular sliding groove plate is spliced with the first connecting plate; the inner side of the first rectangular chute plate is sequentially in sliding connection with the first internal thread sliding block and the second internal thread sliding block; the second internal thread sliding block is connected with the second elastic steel bar fixing grate; the first connecting plate is connected with the first bearing plate; the upper part of the first screw rod is rotationally connected with a first driving wheel; the outer ring of the first driving wheel is in transmission connection with a second driving wheel through a belt; the axle center of the second transmission wheel is rotationally connected with the second screw rod; the outer surface of the second screw rod is sequentially sleeved with a second bearing plate, a third internal thread sliding block, a fourth internal thread sliding block and a third bearing plate; the inner side of the second rectangular chute plate is sequentially in sliding connection with the third internal thread sliding block and the fourth internal thread sliding block; the second bearing plate is connected with the second connecting plate; the lower part of the second connecting plate is connected with a second rectangular sliding groove plate; the lower part of the second rectangular sliding groove plate is connected with a third connecting plate; the second elastic steel bar fixing grate is connected with a third internal thread sliding block; the fourth internal thread sliding block is connected with the first elastic steel bar fixing grate; the third bearing plate is connected with the third connecting plate; the lower part of the third connecting plate is connected with the first gathering plate; the first assembly plate is connected with the long-distance transmission electric slide rail below.

Further, the first shifting reversing mechanism comprises a first power motor, a first motor plate, a first limiting base sliding block, a surface sliding groove plate, a first dislocation electric push rod, a fourth connecting plate, a second collecting plate, a first control disc, a first linkage convex column, a first hollow shifting rod, a second fulcrum convex column, a shifting curved plate and a layered plate; the lower part of the first power motor is sleeved with the first motor plate; the lower part of the first motor plate is connected with a first limiting base sliding block through a bolt; the lower part of the first limiting base sliding block is in sliding connection with the surface sliding groove plate; the surface sliding groove plate is welded with the fourth connecting plate; one side of the first dislocation electric push rod is connected with the first limiting base sliding block, and the other side of the first dislocation electric push rod is connected with the fourth connecting plate; the lower part of the fourth connecting plate is connected with a second gathering plate; the upper part of the first motor plate is connected with the layered plate; an output shaft of the first power motor is rotationally connected with the first control disc; the lower part of the outer surface of the first control disc is connected with the layered plate; the upper part of the first control disc is inserted with the first linkage convex column; the outer surface of the first linkage convex column is in transmission connection with the first hollow deflector rod; the inner surface of the first hollow deflector rod is in transmission connection with the second fulcrum convex column; the lower part of the second fulcrum convex column is connected with the layered plate; the first hollow deflector rod is welded with the deflector curved plate; the second assembly plate is connected with the machine tool assembly plate.

Further, the closed cutting mechanism comprises a second power motor, a second motor plate, a cutting cabin, a third driving wheel, a first cutting saw blade, a fourth driving wheel, a first rotating shaft rod, a first bearing seat, a fifth driving wheel, a sixth driving wheel, a second cutting saw blade, a first lateral supporting leg, a second lateral supporting leg, a first electric lifting door, a second electric lifting door, a first saw blade fixing sleeve and a second saw blade fixing sleeve; the lower part of the second power motor is connected with a second motor plate through bolts; the second motor plate is connected with the cutting cabin; an output shaft of the second power motor is rotationally connected with the third driving wheel; the axle center of the third driving wheel is rotationally connected with the first cutting saw blade; the outer surface of the first cutting saw blade is connected with the cutting cabin; the outer surface of the first cutting saw blade is sleeved with the second saw blade fixing sleeve; the second saw blade fixing sleeve is connected with the cutting cabin; the outer ring of the third driving wheel is in transmission connection with the fourth driving wheel through a belt; the axle center of the fourth driving wheel is rotationally connected with the first rotating shaft rod; the outer surface of the first rotating shaft rod is sleeved with the first bearing seat; the lower part of the first bearing seat is connected with the cutting cabin; the first rotating shaft rod is rotationally connected with the fifth driving wheel; the outer ring of the fifth driving wheel is in transmission connection with the sixth driving wheel through a belt; the axis of the sixth driving wheel is rotationally connected with the second cutting saw blade; the outer surface of the second cutting saw blade is sequentially connected with the cutting cabin and the first saw blade fixing sleeve; the first saw blade fixing sleeve is connected with the cutting cabin; a first electric lifting door is arranged on one side of the cutting cabin, and a second electric lifting door is arranged on the other side of the cutting cabin; one side of the cutting cabin is connected with the first lateral support leg, and the other side of the cutting cabin is connected with the second lateral support leg; the lower part of the second lateral supporting foot is connected with a machine tool collecting plate; the lower part of the first lateral support leg is connected with a first lateral machine bed plate; the upper part of the cutting cabin is connected with a stone powder processing mechanism.

Further, the stone powder treatment mechanism comprises an air pump, a first feeding pipe, a second feeding pipe, a first discharging pipe, a second discharging pipe, a stone powder treatment cabin, a third collecting plate and a detachable sealing door; one side of the air pump is inserted into the first feeding pipe, and the other side of the air pump is inserted into the second feeding pipe; the upper part of the air pump is sequentially connected with the first discharging pipe and the second discharging pipe in an inserting mode; the mountain flour processing cabin is sequentially spliced with the first discharge pipe and the second discharge pipe; the upper part of the third collecting plate is sequentially connected with a stone powder treatment cabin and an air pump; the upper part of the stone powder processing cabin is connected with a detachable sealing door; the lower part of the third collecting plate is connected with an elevating platform column; the first feeding pipe and the second feeding pipe are connected with the cutting cabin below.

Furthermore, the detachable sealing door comprises a main door plate, a limiting frame, an outer exposed plate, a first wiring plug, a handle, a second wiring plug and an inner electromagnetic plate, wherein the main door plate, the limiting frame, the outer exposed plate, the first wiring plug, the handle, the second wiring plug and the inner electromagnetic plate are connected; the upper part of the main door plate is connected with the limiting frame for sleeving; the inner side of the limit frame is sleeved with the exposed plate on the outer side; a first wiring plug, a handle and a second wiring plug are sequentially arranged above the outer exposed plate; the lower part of the outer exposed plate is connected with the inner electromagnetic plate; the outer side of the main door plate is connected with the stone powder processing cabin.

Further, an inclined plane is arranged below the inner electromagnetic plate.

Furthermore, the reinforcing bars formed by the first elastic reinforcing steel bar fixing grate and the second elastic reinforcing steel bar fixing grate deform when being stressed and extruded, and the deformation amount of the reinforcing bars at the two sides is smaller than that of the reinforcing bar at the middle part.

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

1. in order to solve the problems that in the prior art, granite is not uniform enough in shape and cannot be cut automatically by a uniform cutting instrument, the granite is cut and chiseled in a matched mode manually in the stone processing process, meanwhile, a large amount of stone powder can be generated in the cutting process, the iron content of the granite stone powder is high, the stone powder generated by cutting in the manual cutting process floats in the air, even if protective measures are taken manually, the particle size of the stone powder is small, part of the stone powder can enter a human body through a respiratory tract, further, when the granite is chiseled manually, the broken shape of the granite cannot be controlled, the uneven section of the stone can be caused, meanwhile, when the cutting is controlled manually, the lung disease pneumoconiosis can be caused by the fact that the stone powder with high iron content is floated for a long time, and meanwhile, the subsequent application cannot be carried out due to the existence of iron, the stone powder enters the nature to influence the growth of animals and plants and destroy the ecological environment;

2. a clamping moving control mechanism, a first shifting reversing mechanism, a closed cutting mechanism, a stone powder processing mechanism and a second shifting reversing mechanism are designed, when in use, firstly the clamping moving control mechanism clamps and fixes granite ore, then a real-time control screen controls a long-distance transmission electric slide rail to drive the clamping moving control mechanism to communicate with the granite ore to be conveyed into the closed cutting mechanism, and simultaneously the closed cutting mechanism is switched on to operate, then the closed cutting mechanism carries out double-side cutting processing on the granite ore in a sealing way, and simultaneously the stone powder processing mechanism is controlled to pump stone powder generated by cutting in the closed cutting mechanism out of the closed cutting mechanism and enter the stone powder processing mechanism to separate iron-containing particles in the stone powder, then the long-distance transmission electric slide rail drives the clamping moving control mechanism to move to the original position, and simultaneously the clamping moving control mechanism releases the ore fixing state, the first shifting reversing mechanism is matched with the second shifting reversing mechanism to perform steering operation on the ore, so that other irregular surfaces of the ore are cut;

3. realized the fixed granite ore of automatic centre gripping, broken away from the manpower cutting, the mode of having adopted closed cutting simultaneously has stopped the mountain flour and has dissociated the problem that influences the health to the air in by human body suction, the multiaspect cutting to the granite ore has simultaneously adopted the mode of automatic ore upset, multistep switching-over cutting obtains granite stone side, carries out the deironing operation to the higher granite mountain flour of iron content simultaneously, has obtained the effect that can carry out the pure granite mountain flour of follow-up processing use.

Drawings

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

FIG. 2 is a schematic structural view of a clamping movement control mechanism according to the present invention;

FIG. 3 is a schematic structural view of a first toggle reversing mechanism of the present invention;

FIG. 4 is a schematic view of a first perspective of the enclosed cutting mechanism of the present invention;

FIG. 5 is a schematic diagram of a second perspective view of the enclosed cutting mechanism of the present invention;

FIG. 6 is a schematic view of the stone dust processing mechanism of the present invention;

FIG. 7 is a schematic view of a first perspective view of the removable sealing door of the present invention;

fig. 8 is a schematic view of a second three-dimensional structure of the detachable sealing door of the present invention.

The labels in the figures are: 1-machine tool gathering plate, 2-first side machine tool plate, 3-elevated table column, 4-real-time control screen, 5-long distance transmission electric slide rail, 6-clamping movement control mechanism, 7-first toggle reversing mechanism, 8-closed cutting mechanism, 9-stone powder processing mechanism, 10-second toggle reversing mechanism, 11-three-leg chassis, 601-servo motor, 602-first gathering plate, 603-first screw rod, 604-first internal thread slide block, 605-first rectangular slide groove plate, 606-second internal thread slide block, 607-first bearing plate, 608-first connecting plate, 609-first transmission wheel, 6010-first elastic steel bar fixing grate, 6011-second elastic steel bar fixing grate, 6012-second transmission wheel, 6013-second bearing plate, 6014-second joint plate, 6015-second screw rod, 6016-third internal thread slider, 6017-second rectangular chute plate, 6018-fourth internal thread slider, 6019-third bearing plate, 6020-third joint plate, 701-first power motor, 702-first motor plate, 703-first limit base slider, 704-surface chute plate, 705-first dislocation electric push rod, 706-fourth joint plate, 707-second collection plate, 708-first control disc, 709-first linkage convex column, 7010-first hollow driving lever, 7011-second convex column, 7012-toggle curved plate, 7013-layered plate, 801-second power motor, 802-second motor plate, 803-cutting cabin, 804-third transmission wheel, 805-a first cutting saw blade, 806-a fourth driving wheel, 807-a first rotating shaft rod, 808-a first bearing seat, 809-a fifth driving wheel, 8010-a sixth driving wheel, 8011-a second cutting saw blade, 8012-a first lateral support foot, 8013-a second lateral support foot, 8014-a first electric lifting door, 8015-a second electric lifting door, 8016-a first saw blade fixing sleeve, 8017-a second saw blade fixing sleeve, 901-an air pump, 902-a first feeding pipe, 903-a second feeding pipe, 904-a first discharging pipe, 905-a second discharging pipe, 906-a stone dust processing cabin, 907-a third collecting plate, 908-a detachable sealing door, 90801-a joint main door plate, 90802-a limiting frame, 90803-an outer side exposed plate, 90804-a first wiring plug, 90805-handle, 90806-second terminal plug, 90807-internal electromagnetic plate.

Detailed Description

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

Examples

A granite ore processing device is shown in figures 1-8 and comprises a machine tool assembly plate 1, a first side machine tool plate 2, an elevating table column 3, a real-time control screen 4, a long-distance transmission electric slide rail 5, a clamping movement control mechanism 6, a first shifting reversing mechanism 7, a closed cutting mechanism 8, a stone powder processing mechanism 9, a second shifting reversing mechanism 10 and a tripod base plate 11; the lower part of the machine tool assembly plate 1 is welded with a tripod chassis 11; a machine tool assembling plate 1 is welded with a first side machine tool plate 2; one side of the machine tool assembly plate 1 is connected with a first toggle reversing mechanism 7, and the other side of the machine tool assembly plate 1 is connected with a second toggle reversing mechanism 10; the upper part of the machine tool assembly plate 1 is connected with a long-distance transmission electric slide rail 5; the upper part of the first side machine bed plate 2 is welded with an elevating platform column 3; the elevating platform column 3 is connected with the real-time control screen 4; the upper part of the elevated platform column 3 is connected with a stone powder treatment mechanism 9; the stone powder treatment mechanism 9 is connected with the closed cutting mechanism 8; the lower part of the closed cutting mechanism 8 is sequentially connected with a machine tool assembling plate 1 and a first side machine tool plate 2; the upper part of the long-distance transmission electric slide rail 5 is connected with a clamping movement control mechanism 6.

The clamping and moving control mechanism 6 comprises a servo motor 601, a first gathering plate 602, a first lead screw 603, a first internal thread slider 604, a first rectangular chute plate 605, a second internal thread slider 606, a first bearing plate 607, a first connecting plate 608, a first transmission wheel 609, a first elastic rebar fixing grate 6010, a second elastic rebar fixing grate 6011, a second transmission wheel 6012, a second bearing plate 6013, a second connecting plate 6014, a second lead screw 6015, a third internal thread slider 6016, a second rectangular chute plate 6017, a fourth internal thread slider 6018, a third bearing plate 6019 and a third connecting plate 6020; an output shaft of the servo motor 601 is rotatably connected with the first screw rod 603; the lower part of the servo motor 601 is sleeved with the first collecting plate 602; the outer surface of the first screw 603 is sequentially sleeved with a first internal thread sliding block 604, a second internal thread sliding block 606 and a first bearing plate 607; the first internal thread sliding block 604 is connected with the first elastic steel bar fixing grate 6010; one side of the first rectangular chute plate 605 is inserted into the first collection plate 602, and the other side of the first rectangular chute plate 605 is inserted into the first connection plate 608; the inner side of the first rectangular chute plate 605 is sequentially connected with a first internal thread sliding block 604 and a second internal thread sliding block 606 in a sliding manner; the second internal thread sliding block 606 is connected with a second elastic steel bar fixing grate 6011; the first connector tile 608 is connected to the first bearing plate 607; the upper part of the first screw rod 603 is rotationally connected with a first driving wheel 609; the outer ring of the first driving wheel 609 is in driving connection with a second driving wheel 6012 through a belt; the axle center of the second driving wheel 6012 is rotatably connected with a second screw rod 6015; the outer surface of the second screw 6015 is sequentially sleeved with a second bearing plate 6013, a third internal thread slider 6016, a fourth internal thread slider 6018 and a third bearing plate 6019; the inner side of the second rectangular sliding chute plate 6017 is sequentially in sliding connection with a third internal thread sliding block 6016 and a fourth internal thread sliding block 6018; the second bearing plate 6013 is connected to a second joint plate 6014; a second rectangular chute plate 6017 is connected to the lower side of the second connecting plate 6014; a third connecting plate 6020 is connected below the second rectangular sliding groove plate 6017; the second elastic steel bar fixing grate 6011 is connected with a third internal thread sliding block 6016; the fourth internal thread sliding block 6018 is connected with the first elastic steel bar fixing grate 6010; the third bearing plate 6019 is connected to the third adapter plate 6020; the lower part of the third connecting plate 6020 is connected with the first gathering plate 602; the lower part of the first collecting plate 602 is connected with a long-distance transmission electric slide rail 5.

The first toggle reversing mechanism 7 comprises a first power motor 701, a first motor plate 702, a first limiting base sliding block 703, a surface sliding groove plate 704, a first dislocation electric push rod 705, a fourth connecting plate 706, a second collecting plate 707, a first control disc 708, a first linkage convex column 709, a first hollow toggle rod 7010, a second fulcrum convex column 7011, a toggle curved plate 7012 and a layered plate 7013; the lower part of the first power motor 701 is sleeved with a first motor plate 702; the lower part of the first motor plate 702 is connected with a first limit base sliding block 703 through a bolt; the lower part of the first limiting base sliding block 703 is in sliding connection with a surface sliding groove plate 704; the surface runner plate 704 is welded to the fourth connector plate 706; one side of the first dislocation electric push rod 705 is connected with the first limit base sliding block 703, and the other side of the first dislocation electric push rod 705 is connected with the fourth connecting plate 706; a second collective plate 707 is connected to the lower side of the fourth connecting plate 706; the upper part of the first motor plate 702 is connected with the layered plate 7013; an output shaft of the first power motor 701 is rotatably connected with the first control disc 708; the lower part of the outer surface of the first control disc 708 is connected with the layered plate 7013; the upper part of the first control disc 708 is inserted into the first linkage convex column 709; the outer surface of the first linkage convex column 709 is in transmission connection with a first hollow shift lever 7010; the inner surface of the first hollow shift lever 7010 is in transmission connection with the second fulcrum convex column 7011; the lower part of the second fulcrum convex column 7011 is connected with a layered plate 7013; the first hollow deflector rod 7010 is welded with the deflector curved plate 7012; the second collective plate 707 is connected to the machine tool collective plate 1.

The closed cutting mechanism 8 comprises a second power motor 801, a second motor plate 802, a cutting cabin 803, a third driving wheel 804, a first cutting saw blade 805, a fourth driving wheel 806, a first rotating shaft rod 807, a first bearing block 808, a fifth driving wheel 809, a sixth driving wheel 8010, a second cutting saw blade 8011, a first lateral foot 8012, a second lateral foot 8013, a first electric lifting door 8014, a second electric lifting door 8015, a first saw blade fixing sleeve 8016 and a second saw blade fixing sleeve 8017; the lower part of the second power motor 801 is connected with a second motor plate 802 through bolts; the second motor board 802 is connected with the cutting cabin 803; an output shaft of the second power motor 801 is rotatably connected with a third driving wheel 804; the axle center of the third driving wheel 804 is rotationally connected with the first cutting saw blade 805; the outer surface of the first cutting blade 805 is connected to the cutting chamber 803; the outer surface of first cutting blade 805 is sleeved with second blade retaining sleeve 8017; a second blade retaining sleeve 8017 is attached to the cutting chamber 803; the outer ring of the third driving wheel 804 is in transmission connection with a fourth driving wheel 806 through a belt; the axle center of the fourth transmission wheel 806 is rotationally connected with the first rotating shaft rod 807; the outer surface of the first rotating shaft rod 807 is sleeved with a first bearing seat 808; the lower part of the first bearing seat 808 is connected with the cutting cabin 803; the first rotating shaft rod 807 is rotationally connected with a fifth driving wheel 809; the outer ring of the fifth driving wheel 809 is in driving connection with the sixth driving wheel 8010 through a belt; the axis of the sixth driving wheel 8010 is rotatably connected with the second cutting blade 8011; the outer surface of the second cutting blade 8011 is in turn connected to the cutting chamber 803 and the first blade retaining sleeve 8016; a first blade retaining sleeve 8016 is attached to the cutting chamber 803; a first electric lifting door 8014 is arranged on one side of the cutting chamber 803, and a second electric lifting door 8015 is arranged on the other side of the cutting chamber 803; the cutting chamber 803 is connected on one side to a first lateral foot 8012 and on the other side to a second lateral foot 8013; the lower part of the second lateral support foot 8013 is connected with the machine tool collecting plate 1; the lower part of the first lateral support foot 8012 is connected with a first lateral bed plate 2; the cutting cabin 803 is connected with the stone dust processing mechanism 9.

The stone powder treatment mechanism 9 comprises an air pump 901, a first feeding pipe 902, a second feeding pipe 903, a first discharging pipe 904, a second discharging pipe 905, a stone powder treatment cabin 906, a third collecting plate 907 and a detachable sealing door 908; one side of the air pump 901 is inserted into the first feeding pipe 902, and the other side of the air pump 901 is inserted into the second feeding pipe 903; the upper part of the air pump 901 is sequentially connected with a first discharge pipe 904 and a second discharge pipe 905 in an inserting manner; the stone powder treatment cabin 906 is sequentially spliced with a first discharge pipe 904 and a second discharge pipe 905; the upper part of the third collecting plate 907 is sequentially connected with a stone powder treatment cabin 906 and an air pump 901; the upper part of the stone powder processing cabin 906 is connected with a detachable sealing door 908; the lower part of the third gathering plate 907 is connected with an elevating platform column 3; the cutting module 803 is connected below both the first and

second feed tubes

902, 903.

The detachable sealing door 908 comprises a main door panel 90801, a limit frame 90802, an outer exposed plate 90803, a first wiring plug 90804, a handle 90805, a second wiring plug 90806 and an inner electromagnetic plate 90807; the upper part of the main door panel 90801 is connected with a limit frame 90802 for sleeve joint; the inner side of the limit frame 90802 is sleeved with the outer side exposed plate 90803; a first wiring plug 90804, a handle 90805 and a second wiring plug 90806 are sequentially arranged above the outer exposed plate 90803; the lower part of the outer exposed plate 90803 is connected with an inner electromagnetic plate 90807; the outer side of the main door panel 90801 is connected with the stone powder processing cabin 906.

And an inclined plane is arranged below the inner electromagnetic plate 90807.

The reinforcing bars formed by the first and second steel

bar fixing grates

6010 and 6011 are deformed when being pressed by a force, and the deformation amount of the reinforcing bars at both sides is smaller than that of the reinforcing bar at the middle part.

The working principle is as follows: when the granite ore processing device is used, firstly, the device is stably fixed on a working plane, then, the prepared granite ore is fixed inside the clamping and moving control mechanism 6, then, a power supply is connected externally, the real-time control screen 4 is manually opened, then, the power system inside the device is controlled to be switched on through the real-time control screen 4, then, firstly, the clamping and moving control mechanism 6 clamps and fixes the granite ore, then, the real-time control screen 4 controls the long-distance transmission electric slide rail 5 to drive the clamping and moving control mechanism 6 to be communicated with the granite ore to be conveyed into the closed cutting mechanism 8, meanwhile, the closed cutting mechanism 8 is switched on to operate, then, the closed cutting mechanism 8 carries out double-side cutting processing on the granite ore in a sealing way, and meanwhile, the mountain flour processing mechanism 9 is controlled to pump the mountain flour generated by cutting inside the closed cutting mechanism 8 away from the closed cutting mechanism, enters the stone powder treatment mechanism 9 to separate iron-containing particles in the stone powder, then the long-distance transmission electric slide rail 5 drives the clamping movement control mechanism 6 to move and recover to the original position, meanwhile, the clamping movement control mechanism 6 releases the state of fixing the ore, the first toggle reversing mechanism 7 cooperates with the second toggle reversing mechanism 10 to perform steering operation on the ore, further cutting other irregular surfaces of the ore, realizing automatic clamping and fixing of the granite ore, getting rid of manual cutting, meanwhile, the closed cutting mode is adopted to avoid the problem that the mountain flour is dissociated into the air and is inhaled by the human body to influence the health of the human body, meanwhile, aiming at the multi-surface cutting of granite ores, an automatic ore turning mode is adopted, and the granite stone is obtained by multi-step reversing cutting, meanwhile, the iron removal operation is carried out on the granite powder with higher iron content, so that the effect of pure granite powder which can be used for subsequent processing is obtained.

Firstly, ores to be processed are placed above a first elastic steel bar fixing grate 6010, then a servo motor 601 is controlled to be switched on through a real-time control screen 4, then the servo motor 601 drives a first lead screw 603 to rotate, then the first lead screw 603 drives a first driving wheel 609 to rotate, then the first driving wheel 609 drives a second driving wheel 6012 to rotate, then the second driving wheel 6012 drives a second lead screw 6015 to rotate, further the second lead screw 6015 rotates, a fourth internal thread slider 6018 moves upwards, a third internal thread slider 6016 moves downwards, simultaneously the first lead screw 603 rotates, a first internal thread slider 604 moves upwards, simultaneously a second internal thread slider 606 moves downwards, further the first internal thread slider 604, the second internal thread slider 606, the third internal thread slider 6016 and the fourth internal thread slider 6018 simultaneously drive a first elastic steel bar fixing grate 6010 and a second elastic steel bar fixing grate 6011 to be close to each other, and then carry out the centre gripping with the granite ore and fix, then servo motor 601 stall, then long distance transmission electric slide rail 5 drives whole centre gripping mobility control mechanism 6 and enters into inside the cutting mechanism 8 that seals with the ore and cut, has accomplished the fixed and conveying of granite ore.

After the clamping and moving control mechanism 6 enters the closed cutting mechanism 8 and finishes primary cutting, the clamping and moving control mechanism 6 releases the fixation of granite ore, then the real-time control screen 4 controls the first dislocation electric push rod 705 to drive the first motor plate 702 to slide above the surface chute plate 704 until the first hollow deflector rod 7010 and the shifting curved plate 7012 extend into the clamping and moving control mechanism 6, meanwhile, the first power motor 701 drives the first control disc 708 to rotate, then the first control disc 708 drives the first hollow deflector rod 7010 to shift through the first linkage convex column 709, meanwhile, the second pivot convex column 7011 is used as a pivot to drive the first hollow deflector rod 7010 to change the direction, then when the first hollow deflector rod 7010 is driven by the first control disc 708 to be far away from the clamping and moving control mechanism 6, the curved plate 7012 is shifted to shift the granite ore, simultaneously the second is stirred reversing mechanism 10 and is carried out the reverse operation to the opposite side of granite ore, and granite ore is stirred by two reverse power in both sides promptly, rotates granite, then first dislocation electric putter 705 contracts and drives the first reversing mechanism 7 that stirs and move to the original position, and then has realized the automatic upset of granite.

After the long-distance transmission electric sliding rail 5 drives the clamping movement control mechanism 6 to move to the cutting cabin 803, then the first electric lifting door 8014 and the second electric lifting door 8015 are controlled to descend and close, then the power supply of the second power motor 801 is controlled to be switched on through the real-time control screen 4 to rotate, then the second power motor 801 drives the third driving wheel 804 to rotate, then the third driving wheel 804 drives the fourth driving wheel 806 to rotate, then the fourth driving wheel 806 drives the first rotating shaft rod 807 to rotate, further the first rotating shaft rod 807 drives the fifth driving wheel 809 through the real-time control screen 4, further the fifth driving wheel 809 drives the sixth driving wheel 8010 to rotate, then the sixth driving wheel 8010 drives the second cutting saw blade 8011 to rotate, meanwhile, the third driving wheel 804 drives the first cutting saw blade 805 to rotate, further the second cutting saw blade 8011 and the first cutting saw blade 805 simultaneously rotate to perform double-side cutting on the ore in the cutting cabin 803, after the first toggle reversing mechanism 7 and the second toggle reversing mechanism 10 drive the granite ore to switch directions, the granite ore is cut again, and the cutting of the granite is completed.

second feed tubes

902, 903.

When the closed cutting mechanism 8 cuts granite, mountain flour generated by cutting floats in the air, the power supply of the air pump 901 is switched on through the real-time control screen 4, then the air pump 901 collects mountain flour inside the cutting cabin 803 into the air pump 901 through the first feeding pipe 902 and the second feeding pipe 903, then the mountain flour enters the mountain flour processing cabin 906 through the first discharging pipe 904 and the second discharging pipe 905, then the mountain flour processing cabin 906 collects the mountain flour, the power supply of the detachable sealing door 908 is switched on through the control of the real-time control screen 4, then the detachable sealing door 908 collects and separates iron-containing parts inside the mountain flour, and the collection of the mountain flour and the separation of iron inside the mountain flour are completed.

Firstly, the mountain flour is blown to the interior of a mountain flour processing cabin 906 from a first discharge pipe 904 and a second discharge pipe 905, the direction of air flow is blown to an inner electromagnetic plate 90807 firstly, then the iron-containing components in the mountain flour are attracted and separated by the inner electromagnetic plate 90807, after the use is finished, the outer exposed plate 90803 and the inner electromagnetic plate 90807 can be taken out through a handle 90805, then electric wires of a first wiring plug 90804 and a second wiring plug 90806 are pulled out, then the iron powder components fall from the inner electromagnetic plate 90807, the iron powder is collected, and the separation of impurity iron powder components in the mountain flour is finished.

The inside electromagnetic plate 90807 below sets up to the inclined plane to carry the air current of mountain flour to blow through along inside electromagnetic plate 90807 surface, and then inside electromagnetic plate 90807 attracts the iron powder that wherein carries to collect.

The reinforcing steel bars used by the first and second elastic reinforcing steel

bar fixing grates

6010 and 6011 are deformed when being pressed by force, and the deformation amount of the reinforcing steel bars at the two sides is smaller than that of the reinforcing steel bar at the middle part, so that the granite ore can be fixed by being attached to the irregular shape of the granite ore.

The technical solutions of the present invention or similar technical solutions designed by those skilled in the art based on the teachings of the technical solutions of the present invention are all within the scope of the present invention to achieve the above technical effects.

Claims

1. A granite ore processing device comprises a machine tool assembling plate (1), a first side machine tool plate (2), an elevating table column (3) and a real-time control screen (4), and is characterized by further comprising a long-distance transmission electric slide rail (5), a clamping movement control mechanism (6), a first stirring reversing mechanism (7), a closed cutting mechanism (8), a stone powder processing mechanism (9), a second stirring reversing mechanism (10) and a three-leg chassis (11); the lower part of the machine tool assembly plate (1) is welded with a tripod chassis (11); a machine tool assembly plate (1) is welded with a first side machine tool plate (2); one side of the machine tool assembly plate (1) is connected with a first toggle reversing mechanism (7), and the other side of the machine tool assembly plate (1) is connected with a second toggle reversing mechanism (10); the upper part of the machine tool assembly plate (1) is connected with a long-distance transmission electric slide rail (5); the upper part of the first side machine bed plate (2) is welded with an elevated platform column (3); the elevating platform column (3) is connected with the real-time control screen (4); the upper part of the elevated platform column (3) is connected with a stone powder treatment mechanism (9); the stone powder processing mechanism (9) is connected with the closed cutting mechanism (8); the lower part of the closed cutting mechanism (8) is sequentially connected with a machine tool assembling plate (1) and a first side machine tool plate (2); the upper part of the long-distance transmission electric slide rail (5) is connected with a clamping movement control mechanism (6).

2. A granite ore processing apparatus according to claim 1, where the clamping movement control mechanism (6) comprises a servo motor (601), a first gathering plate (602), a first lead screw (603), a first female screw slider (604), a first rectangular chute plate (605), a second female screw slider (606), a first bearing plate (607), a first link plate (608), a first transmission wheel (609), a first spring-loaded bar-fixed grate (6010), a second spring-loaded bar-fixed grate (6011), a second transmission wheel (6012), a second bearing plate (6013), a second link plate (6014), a second lead screw (6015), a third female screw slider (6016), a second rectangular chute plate (6017), a fourth female screw slider (6018), a third bearing plate (6019) and a third link plate (6020); an output shaft of the servo motor (601) is rotationally connected with the first screw rod (603); the lower part of the servo motor (601) is sleeved with the first collecting plate (602); the outer surface of the first screw rod (603) is sequentially sleeved with a first internal thread sliding block (604), a second internal thread sliding block (606) and a first bearing plate (607); the first internal thread sliding block (604) is connected with a first elastic steel bar fixed grate (6010); one side of the first rectangular sliding groove plate (605) is spliced with the first gathering plate (602), and the other side of the first rectangular sliding groove plate (605) is spliced with the first connecting plate (608); the inner side of the first rectangular chute plate (605) is sequentially connected with a first internal thread sliding block (604) and a second internal thread sliding block (606) in a sliding manner; the second internal thread sliding block (606) is connected with a second elastic steel bar fixing grate (6011); the first connecting plate (608) is connected with the first bearing plate (607); the upper part of the first screw rod (603) is rotationally connected with a first driving wheel (609); the outer ring of the first transmission wheel (609) is in transmission connection with a second transmission wheel (6012) through a belt; the axle center of the second transmission wheel (6012) is rotationally connected with a second screw rod (6015); the outer surface of the second screw rod (6015) is sequentially sleeved with a second bearing plate (6013), a third internal thread sliding block (6016), a fourth internal thread sliding block (6018) and a third bearing plate (6019); the inner side of the second rectangular chute plate (6017) is sequentially in sliding connection with a third internal thread sliding block (6016) and a fourth internal thread sliding block (6018); the second bearing plate (6013) is connected with a second connecting plate (6014); a second rectangular sliding groove plate (6017) is connected with the lower part of the second connecting plate (6014); the lower part of the second rectangular sliding groove plate (6017) is connected with a third connecting plate (6020); the second elastic steel bar fixed grate (6011) is connected with a third internal thread sliding block (6016); a fourth internal thread sliding block (6018) is connected with the first elastic steel bar fixing grate (6010); the third bearing plate (6019) is connected with the third connecting plate (6020); the lower part of the third connecting plate (6020) is connected with the first gathering plate (602); the lower part of the first gathering plate (602) is connected with a long-distance transmission electric slide rail (5).

3. The granite ore processing device according to claim 2, wherein the first toggle reversing mechanism (7) comprises a first power motor (701), a first motor plate (702), a first limit base sliding block (703), a surface chute plate (704), a first dislocation electric push rod (705), a fourth connecting plate (706), a second collecting plate (707), a first control disc (708), a first linkage convex column (709), a first hollow shift lever (7010), a second fulcrum convex column (7011), a toggle curved plate (7012) and a layered plate (7013); the lower part of the first power motor (701) is sleeved with a first motor plate (702); the lower part of the first motor plate (702) is connected with a first limiting base sliding block (703) through a bolt; the lower part of the first limiting base sliding block (703) is in sliding connection with the surface sliding groove plate (704); the surface sliding groove plate (704) is welded with the fourth connecting plate (706); one side of the first dislocation electric push rod (705) is connected with the first limit base sliding block (703), and the other side of the first dislocation electric push rod (705) is connected with the fourth connecting plate (706); a second gathering plate (707) is connected to the lower side of the fourth connecting plate (706); the upper part of the first motor plate (702) is connected with the layered plate (7013); an output shaft of the first power motor (701) is rotationally connected with the first control disc (708); the lower part of the outer surface of the first control disc (708) is connected with a layered plate (7013); the upper part of the first control disc (708) is spliced with the first linkage convex column (709); the outer surface of the first linkage convex column (709) is in transmission connection with a first hollow deflector rod (7010); the inner surface of the first hollow deflector rod (7010) is in transmission connection with the second fulcrum convex column (7011); the lower part of the second fulcrum convex column (7011) is connected with a layered plate (7013); the first hollow deflector rod (7010) is welded with the deflector curved plate (7012); the second assembly plate (707) is connected to the machine tool assembly plate (1).

4. A granite ore processing apparatus according to claim 3, where the closed cutting mechanism (8) comprises a second power motor (801), a second motor plate (802), a cutting chamber (803), a third driving wheel (804), a first cutting blade (805), a fourth driving wheel (806), a first rotating shaft rod (807), a first bearing seat (808), a fifth driving wheel (809), a sixth driving wheel (8010), a second cutting blade (8011), a first lateral foot (8012), a second lateral foot (8013), a first electrically operated lift gate (8014), a second electrically operated lift gate (8015), a first blade retaining sleeve (8016) and a second blade retaining sleeve (8017); the lower part of the second power motor (801) is connected with a second motor plate (802) through bolts; the second motor plate (802) is connected with the cutting cabin (803); an output shaft of the second power motor (801) is rotationally connected with the third transmission wheel (804); the axle center of the third driving wheel (804) is rotationally connected with the first cutting saw blade (805); the outer surface of the first cutting saw blade (805) is connected with the cutting cabin (803); the outer surface of the first cutting saw blade (805) is sleeved with the second saw blade fixing sleeve (8017); the second saw blade fixing sleeve (8017) is connected with the cutting cabin (803); the outer ring of the third driving wheel (804) is in transmission connection with a fourth driving wheel (806) through a belt; the axle center of the fourth transmission wheel (806) is rotationally connected with the first rotating shaft rod (807); the outer surface of the first rotating shaft rod (807) is sleeved with a first bearing seat (808); the lower part of the first bearing seat (808) is connected with the cutting cabin (803); the first rotating shaft rod (807) is rotationally connected with a fifth driving wheel (809); the outer ring of the fifth driving wheel (809) is in transmission connection with the sixth driving wheel (8010) through a belt; the axis of the sixth driving wheel (8010) is rotatably connected with the second cutting saw blade (8011); the outer surface of the second cutting saw blade (8011) is sequentially connected with the cutting cabin (803) and the first saw blade fixing sleeve (8016); the first saw blade fixing sleeve (8016) is connected with the cutting cabin (803); a first electric lifting door (8014) is arranged on one side of the cutting cabin (803), and a second electric lifting door (8015) is arranged on the other side of the cutting cabin (803); the cutting chamber (803) is connected on one side to the first lateral foot (8012) and on the other side to the second lateral foot (8013); the lower part of the second lateral supporting foot (8013) is connected with a machine tool gathering plate (1); the lower part of the first lateral supporting leg (8012) is connected with a first lateral machine bed board (2); the upper part of the cutting cabin (803) is connected with a stone powder processing mechanism (9).

5. A granite ore processing plant according to claim 4, where the stone dust treatment means (9) comprises an air pump (901), a first feeding pipe (902), a second feeding pipe (903), a first discharging pipe (904), a second discharging pipe (905), a stone dust treatment chamber (906), a third collecting plate (907) and a detachable sealing door (908); one side of the air pump (901) is inserted into the first feeding pipe (902), and the other side of the air pump (901) is inserted into the second feeding pipe (903); the upper part of the air pump (901) is sequentially spliced with a first discharge pipe (904) and a second discharge pipe (905); the stone powder treatment cabin (906) is sequentially spliced with a first discharge pipe (904) and a second discharge pipe (905); the upper part of the third collecting plate (907) is sequentially connected with a stone powder processing cabin (906) and an air pump (901); the upper part of the stone powder processing cabin (906) is connected with a detachable sealing door (908); the lower part of the third gathering plate (907) is connected with an elevating platform column (3); the lower parts of the first feeding pipe (902) and the second feeding pipe (903) are connected with the cutting cabin (803).

6. A granite ore processing apparatus as claimed in claim 5, where the removable sealing door (908) includes an engaging main door panel (90801), a stop frame (90802), an outside exposure panel (90803), a first wiring plug (90804), a handle (90805), a second wiring plug (90806) and an inside electromagnetic panel (90807); the upper part of the main door panel (90801) is connected with a limit frame (90802) for sleeving; the inner side of the limit frame (90802) is sleeved with the outer exposed plate (90803); a first wiring plug (90804), a handle (90805) and a second wiring plug (90806) are sequentially arranged above the outer side exposed plate (90803); the lower part of the outer exposed plate (90803) is connected with an inner electromagnetic plate (90807); the outer side of the main door panel (90801) is connected with the stone powder processing cabin (906).

7. A granite ore processing plant according to claim 6, where below the inner electromagnetic plate (90807) is arranged a ramp.

8. A granite ore processing device according to claim 7, where the reinforcing bars of the first and second fixing grates (6010, 6011) deform when pressed by force, and the deformation amount of the reinforcing bars at both sides is smaller than that of the reinforcing bar at the middle part.