CN113021655A

CN113021655A - Electrical ore cutting equipment

Info

Publication number: CN113021655A
Application number: CN202110300016.4A
Authority: CN
Inventors: 付家坤; 李大军; 陈志华; 杜璟; 洪兵; 马土平
Original assignee: Engineering Technology Branch Of Tongling Nonferrous Metals Group Co ltd
Current assignee: Engineering Technology Branch Of Tongling Nonferrous Metals Group Co ltd
Priority date: 2021-03-22
Filing date: 2021-03-22
Publication date: 2021-06-25

Abstract

The invention discloses ore electrical cutting equipment, and relates to the technical field of electrical cutting equipment. According to the invention, the equipment box, the cutting cabin, the sliding groove, the gas transmission hole, the dust collecting cabin, the gas cabin, the exhaust hole, the dust cleaning cabin door, the dust collection blade, the transmission shaft, the arc-shaped fan blade, the dust screen, the grating plate, the second hydraulic push rod, the connecting rod, the lifting box, the rotating cabin, the transmission cabin, the gas outlet hole, the gas inlet pipe, the protective partition plate, the cutting blade, the connecting gas pipe, the flow dividing gas pipe, the curved arc-shaped blade, the first rotating shaft, the first gear, the second gear and the second rotating shaft are arranged to realize the rapid cutting of ores, when high-pressure gas enters the exhaust hole, the arc-shaped fan blade, the transmission shaft and the dust collection blade can be driven to rotate, so that dust is sucked into the dust collecting cabin.

Description

Electrical ore cutting equipment

Technical Field

The invention relates to the technical field of electrical cutting equipment, in particular to ore electrical cutting equipment.

Background

The ore refers to a mineral aggregate from which useful components can be extracted or which has certain utilizable properties, and the ore can be divided into metal minerals and nonmetal minerals, wherein the unit content of the useful components in the ore is called ore grade, the precious metal ore such as gold, platinum and the like is expressed by gram/ton, and other ores generally express the common ore grade by percentage to measure the value of the ore, but the content of gangue components and harmful impurities in the effective component ore also affects the value of the ore.

Current ore cutting equipment is when carrying out the cutting of great volume ore, because the size of cutting piece is limited, can't once cut apart the ore completely, need overturn so that cut from one side in addition to the ore, and the upset to the ore generally all adopts the mode of shutting down to go on through artifical upset, this operating method work efficiency is low, and the fixed and dismantlement operation of the repeated ore of upset in-process needs, very big influence the work efficiency of ore cutting processing.

Disclosure of Invention

The invention aims to: in order to solve the problem of low working efficiency of processing of large ores, the ore electrical cutting equipment is provided.

In order to achieve the purpose, the invention provides the following technical scheme: an ore electrical cutting device comprises a device box, a lifting mechanism, a clamping mechanism, a dust suction mechanism and a cutting mechanism, wherein a cutting cabin and a dust cleaning cabin door are arranged on one side of the outer wall of the device box, the dust cleaning cabin door is positioned at two ends below the cutting cabin, a sliding groove and a gas transmission hole are arranged at the bottom end of the inner wall of the cutting cabin, the gas transmission hole is positioned at one side of two ends of the sliding groove, a limiting groove rail is arranged at the bottom end of the inner wall of the sliding groove, a gas cabin is arranged below the gas transmission hole inside the device box, a dust collecting cabin is arranged at one end of the gas cabin, which is positioned at the gas cabin, a vent hole penetrating through the outer wall of the device box is arranged at one end of the gas cabin, which is far away from the dust collecting cabin, the lifting mechanism, the clamping mechanism and the cutting mechanism are positioned inside the cutting cabin, the lifting mechanism, the cutting mechanism is located above the lifting mechanism and penetrates through the top end of the equipment box, and the dust collection mechanism is located inside the dust collection cabin and the air cabin.

As a still further scheme of the invention: the lifting mechanism comprises a lifting platform, a first hydraulic push rod, a first telescopic platform, a second telescopic platform, a telescopic spring, a first normally open switch and a second normally open switch, the lifting platform, the first telescopic platform, the second telescopic platform and the inner wall of the sliding groove are mutually sleeved, the first telescopic platform and the second telescopic platform are respectively positioned at two ends of the lifting platform, a telescopic groove is arranged inside the lifting platform, the telescopic spring is positioned inside the telescopic groove, one ends of the first telescopic platform and the second telescopic platform, which are close to each other, penetrate through the inside of the telescopic groove and are respectively attached to two ends of the telescopic spring, the output end of the first hydraulic push rod is fixedly connected with the bottom end of the lifting platform, the first hydraulic push rod penetrates through the bottom end of the sliding groove to the inside of the equipment box, the telescopic spring and the first normally open switch are positioned below the lifting platform and are fixedly installed at the bottom end of the inner wall of the sliding groove, the telescopic spring and the first normally open switch are respectively positioned at two ends of the first hydraulic push rod.

As a still further scheme of the invention: the clamping mechanism comprises a first movable block, a second movable block, a rotating motor, a clamping push rod, a limiting slide block, a matrix flexible fixture and a rotating bearing, wherein the bottom ends of the first movable block and the second movable block are mutually sleeved with the inner wall of a sliding groove, the first movable block and the second movable block are respectively positioned at one ends, away from the lifting platform, of the first telescopic platform and the second telescopic platform, the limiting slide block is positioned at the bottom ends of the first movable block and the second movable block and is mutually sleeved with the inner wall of a limiting groove rail, the matrix flexible fixture is positioned at one end, close to each other, of the first movable block and the second movable block, the rotating motor and the clamping push rod are positioned at one ends, away from each other, of the first movable block and the second movable block, the clamping push rod is positioned below the rotating motor, the clamping push rod is fixedly connected with the bottom end of the cutting cabin, and the rotating cabin is arranged inside the rotating motor and the second movable block, the rotating bearing is located inside the rotating cabin, one end of the matrix flexible clamp penetrates through the rotating cabin and is connected with the inner wall of the rotating bearing in a sleeved mode, and the output end of the rotating motor penetrates through the rotating cabin and is connected with the rotating bearing.

As a still further scheme of the invention: dust absorption mechanism includes dust collection blade, transmission shaft, arc flabellum, dust screen, grid board, dust collection blade is located inside the air chamber, the transmission shaft is located inside the air chamber, arc flabellum, dust screen cup joint with the inner wall in exhaust hole each other, dust collection blade's both ends are run through respectively to collection dirt cabin, exhaust hole inside and are connected with dust collection blade, arc flabellum, the dust screen is located the arc flabellum and keeps away from dust collection blade's one end, the one end that the air chamber was kept away from in collection dirt cabin runs through to the inside inner wall both ends that are connected with the sliding tray of sliding tray, the grid board is located the contact position of collection dirt cabin and sliding tray.

As a still further scheme of the invention: the cutting mechanism comprises a second hydraulic push rod, a connecting rod, a lifting box, an air inlet pipe, a protective partition plate, a cutting blade, a connecting air pipe, a shunting air pipe, a curved arc-shaped blade, a first rotating shaft, a second gear and a second rotating shaft, wherein the second hydraulic push rod is positioned at the top end of the equipment box, the connecting rod, the lifting box and the air inlet pipe are positioned in the cutting cabin, the lifting box is positioned above the lifting mechanism, the connecting rod and the air inlet pipe are positioned at the top end of the lifting box, the bottom end of the second hydraulic push rod penetrates into the cutting cabin and is connected with the top end of the connecting rod, the protective partition plate and the connecting air pipe are respectively positioned at two ends of the lifting box, the cutting blade is positioned at one end of the protective partition plate, which is far away from the lifting box, the shunting air pipe is positioned at one end of the connecting air pipe, a rotating cabin, a, the venthole is located the inner wall bottom in rotatory cabin and runs through the outer wall to the lift case and be connected the trachea and be connected, curved surface arc blade, axis of rotation are located the inside in rotatory cabin, and curved surface arc blade is located the outer wall side of an axis of rotation, No. one gear, No. two gears, No. two axes of rotation are located the transmission cabin inside, No. two gears are located gear one side, the one end of No. two axes of rotation cup joints each other with the inner wall of No. two gears, the one end of an axis of rotation runs through to the inside and cup joints each other with the inner wall of a gear in transmission cabin, the one end that No. two gears were kept away from to No. two axes of rotation runs through transmission cabin, protective barrier to protective barrier cup joints each other with the cutting piece.

As a still further scheme of the invention: the quantity of rotating the motor is provided with two, No. one normally open switch, No. two normally open switches pass through inside wire electric connection, and No. one normally open switch, No. two normally open switches rotate motor electric connection through outside starting switch.

As a still further scheme of the invention: the one end that the lift case was kept away from to the intake pipe runs through the top of cutting cabin and is connected with outside air pump, the reposition of redundant personnel trachea is kept away from the one end of connecting trachea and is connected with the gas transmission hole, the gas transmission hole runs through to the inside inner wall top that is connected with the gas cabin of equipment box.

As a still further scheme of the invention: the first gear and the second gear are meshed with each other, and the number of teeth of the first gear is larger than that of the teeth of the second gear.

As a still further scheme of the invention: the quantity of curved surface arc blade is provided with a plurality ofly, and is a plurality of curved surface arc blade uses an axis of rotation as central evenly distributed at the outer wall side of an axis of rotation, curved surface arc blade keeps away from one side outer wall of an axis of rotation and laminates mutually with the inner wall in rotatory cabin.

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

1. the device comprises an equipment box, a cutting cabin, a sliding groove, a limiting groove rail, a lifting platform, a telescopic groove, a hydraulic push rod, a telescopic platform II, a telescopic spring, a normally open switch I, a normally open switch II, a movable block I, a movable block II, a rotating motor, a clamping push rod, a limiting slide block, a matrix flexible clamp, a rotating bearing and a rotating cabin, wherein the ore can be quickly turned over;

2. through the arrangement of the equipment box, the cutting cabin, the sliding groove, the air delivery hole, the dust collection cabin, the air cabin, the exhaust hole, the dust removal cabin door, the dust collection blade, the transmission shaft, the arc-shaped fan blade, the dust screen, the grating plate, a second hydraulic push rod, the connecting rod, the lifting box, the rotating cabin, the transmission cabin, the air outlet hole, the air inlet pipe, the protective baffle plate, the cutting blade, the connecting air pipe, the diversion air pipe, the curved arc-shaped blade, the first rotating shaft, the first gear, the second gear and the second rotating shaft, the rapid cutting of ores can be realized, the high-pressure gas enters the rotating cabin through the air inlet pipe to drive the curved arc-shaped blade to rotate, the high-pressure gas in the rotating cabin can drive the arc-shaped fan blade to rotate when entering the exhaust hole through the air outlet hole, the connecting air pipe, the diversion air pipe, the air delivery hole and the, the arc flabellum can drive the rotation of dust absorption blade through the transmission of transmission shaft to can inhale the dust in the dust collecting compartment in the cutting cabin, can effectively improve the utilization ratio of the gas energy through mutually supporting of above a plurality of parts.

Drawings

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

FIG. 2 is an exploded view of the structure of the present invention;

FIG. 3 is a schematic structural view of the equipment box, the lifting mechanism and the clamping mechanism of the present invention;

FIG. 4 is a cross-sectional exploded view of the equipment cabinet of the present invention;

FIG. 5 is an enlarged view of the invention at position A;

FIG. 6 is a cross-sectional exploded view of the lift table of the present invention;

FIG. 7 is a cross-sectional exploded view of the clamping mechanism of the present invention;

FIG. 8 is a structural cross-sectional view of the cutting mechanism of the present invention;

fig. 9 is a cross-sectional exploded view of the cutting mechanism of the present invention.

In the figure: 1. an equipment box; 101. cutting the cabin; 102. a sliding groove; 1021. limiting the groove rail; 103. a gas transmission hole; 104. a dust collection compartment; 105. a gas cabin; 1051. an exhaust hole; 2. a dust removal cabin door; 3. a lifting mechanism; 301. a lifting platform; 3011. a telescopic groove; 302. a first hydraulic push rod; 303. a first telescopic table; 304. a second telescopic table; 305. a tension spring; 306. a first normally open switch; 307. a second normally open switch; 4. a clamping mechanism; 401. a first movable block; 402. a second movable block; 403. rotating the motor; 404. clamping the push rod; 405. a limiting slide block; 406. a matrix flexible clamp; 407. a rotating bearing; 408. rotating the cabin; 5. a dust suction mechanism; 501. a dust-collecting blade; 502. a drive shaft; 503. arc-shaped fan blades; 504. a dust screen; 505. a grid plate; 6. a cutting mechanism; 601. a second hydraulic push rod; 602. a connecting rod; 603. a lifting box; 6031. a rotating cabin; 6032. a transmission cabin; 6033. an air outlet; 604. an air inlet pipe; 605. a protective barrier; 606. cutting the slices; 607. connecting an air pipe; 608. a gas distributing pipe; 609. a curved arc blade; 610. a first rotating shaft; 611. a first gear; 612. a second gear; 613. and a second rotating shaft.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance. In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "disposed" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art. The following describes an embodiment of the present invention based on its overall structure.

Referring to fig. 1 to 9, in an embodiment of the present invention, an ore electrical cutting apparatus includes an apparatus box 1, a lifting mechanism 3, a clamping mechanism 4, a dust suction mechanism 5, and a cutting mechanism 6, a cutting cabin 101 and a dust removal cabin door 2 are disposed on one side of an outer wall of the apparatus box 1, the dust removal cabin door 2 is disposed at two ends below the cutting cabin 101, a sliding groove 102 and a gas transmission hole 103 are disposed at a bottom end of an inner wall of the cutting cabin 101, the gas transmission hole 103 is disposed at one side of two ends of the sliding groove 102, a limiting groove rail 1021 is disposed at a bottom end of an inner wall of the sliding groove 102, an air cabin 105 is disposed inside the apparatus box 1 below the gas transmission hole 103, a dust collection cabin 104 is disposed at one end of the air cabin 105 inside the apparatus box 1, an exhaust hole 1051 penetrating through an outer wall of the apparatus box 1 is disposed at one end of the air cabin 105 far from the dust collection cabin 104, the clamping mechanisms 4 are sleeved with the inner wall of the sliding groove 102, the clamping mechanisms 4 are located at two ends of the lifting mechanism 3, the cutting mechanism 6 is located above the lifting mechanism 3 and penetrates through the top end of the equipment box 1, and the dust collection mechanism 5 is located inside the dust collection cabin 104 and the air cabin 105.

As a preferred embodiment of the invention, the lifting mechanism 3 comprises a lifting platform 301, a first hydraulic push rod 302, a first telescopic platform 303, a second telescopic platform 304, a telescopic spring 305, a first normally open switch 306 and a second normally open switch 307, the lifting platform 301, the first telescopic platform 303 and the second telescopic platform 304 are mutually sleeved with the inner wall of the sliding groove 102, the first telescopic platform 303 and the second telescopic platform 304 are respectively positioned at two ends of the lifting platform 301, a telescopic groove 3011 is arranged in the lifting platform 301, the telescopic spring 305 is positioned in the telescopic groove 3011, one ends of the first telescopic platform 303 and the second telescopic platform 304, which are close to each other, penetrate through the telescopic groove 3011 and are respectively attached to two ends of the telescopic spring 305, the output end of the first hydraulic push rod 302 is fixedly connected with the bottom end of the lifting platform 301, the first hydraulic push rod 302 penetrates through the bottom end of the sliding groove 102 to the inside of the equipment box 1, the telescopic spring 305 and the first normally open switch 306 are positioned below the lifting platform 301 and are fixedly installed at the bottom end of the inner wall of the sliding groove 102, the telescopic spring 305 and the first normally open switch 306 are respectively located at two ends of the first hydraulic push rod 302, and the ore can be lifted through the lifting mechanism 3, so that the ore can be fixed and rotated conveniently.

As a preferred embodiment of the present invention, the clamping mechanism 4 includes a first movable block 401, a second movable block 402, a rotating motor 403, a clamping push rod 404, a limiting slider 405, a matrix flexible clamp 406 and a rotating bearing 407, bottom ends of the first movable block 401 and the second movable block 402 are sleeved with inner walls of the sliding groove 102, the first movable block 401 and the second movable block 402 are respectively located at one ends of the first telescopic platform 303 and the second telescopic platform 304 far away from the lifting platform 301, the limiting slider 405 is located at bottom ends of the first movable block 401 and the second movable block 402 and is sleeved with inner walls of the limiting groove rail 1021, the matrix flexible clamp 406 is located at one end where the first movable block 401 and the second movable block 402 are close to each other, the rotating motor 403 and the clamping push rod 404 are located at one end where the first movable block 401 and the second movable block 402 are far away from each other, the clamping push rod 404 is located below the rotating motor 403, the clamping push rod 404 is fixedly connected with the bottom end of the cutting cabin 101, rotate motor 403, the inside of No. two movable blocks 402 is provided with rotates cabin 408, rolling bearing 407 is located the inside of rotating cabin 408, the one end of matrix flexible clamp 406 is run through to rotate the inside inner wall that cabin 408 is inside cup joints with rolling bearing 407 each other, the output that rotates motor 403 runs through to rotate cabin 408 inside and be connected with rolling bearing 407, can carry out quick centre gripping to the ore through fixture 4 and fix, can adapt to the surperficial centre gripping of ore unevenness through matrix flexible clamp 406, thereby make the centre gripping of ore more firm stable.

As a preferred embodiment of the present invention, the dust suction mechanism 5 comprises a dust suction blade 501, a transmission shaft 502, an arc-shaped fan blade 503, a dust screen 504, and a grid plate 505, wherein the dust suction blade 501 is located inside the air chamber 105, the transmission shaft 502 is located inside the air chamber 105, the arc-shaped fan blade 503, the dust screen 504 and the inner wall of the exhaust hole 1051 are sleeved with each other, two ends of the dust suction blade 501 respectively penetrate through the dust collection compartment 104 and the exhaust hole 1051 to be connected with the dust suction blade 501 and the arc-shaped fan blade 503, the dust screen 504 is located at one end of the arc-shaped fan blade 503 far from the dust suction blade 501, one end of the dust collection compartment 104 far from the air chamber 105 penetrates through the inside of the sliding slot 102 to be connected with two ends of the inner, the dust collection mechanism 5 can collect dust generated in the cutting process into the dust collection cabin 104, so that the dust can be conveniently centralized and treated, and the phenomenon that the dust flies randomly to influence the environment is avoided.

As a preferred embodiment of the invention, the cutting mechanism 6 comprises a second hydraulic push rod 601, a connecting rod 602, a lifting box 603, an air inlet pipe 604, a protective baffle 605, a cutting blade 606, a connecting air pipe 607, a diversion air pipe 608, a curved arc blade 609, a first rotating shaft 610, a second gear 612 and a second rotating shaft 613, the second hydraulic push rod 601 is positioned at the top end of the equipment box 1, the connecting rod 602, the lifting box 603 and the air inlet pipe 604 are positioned inside the cutting cabin 101, the lifting box 603 is positioned above the lifting mechanism 3, the connecting rod 602 and the air inlet pipe 604 are positioned at the top of the lifting box 603, the bottom end of the second hydraulic push rod 601 penetrates through the cutting cabin 101 to be connected with the top end of the connecting rod 602, the protective baffle 605 and the connecting air pipe 607 are respectively positioned at two ends of the lifting box 603, the cutting blade 606 is positioned at one end of the protective baffle 605 far away from the lifting box 603, a rotating cabin 6031, a transmission cabin 6032 and an air outlet 6033 are arranged inside the lifting box 603, the transmission cabin 6032 is positioned at one end of the rotating cabin 6031, the air outlet 6033 is positioned at the bottom end of the inner wall of the rotating cabin 6031 and penetrates through the outer wall of the lifting box 603 to be connected with a connecting air pipe 607, the curved arc-shaped blade 609 and the first rotating shaft 610 are positioned inside the rotating cabin 6031, the curved arc-shaped blade 609 is positioned on the side surface of the outer wall of the first rotating shaft 610, the first gear 611, the second gear 612 and the second rotating shaft 613 are positioned inside the transmission cabin 6032, the second gear 612 is positioned on one side of the first gear 611, one end of the second rotating shaft 613 penetrates through the inside of the transmission cabin 6032 to be mutually sleeved with the inner wall of the first gear 611, one end of the second rotating shaft 613, which is far away from the second gear 612, penetrates through the transmission cabin 6032, one end of the partition 605 to the protective partition 605 is mutually sleeved with the cutting piece, the ore can be cut by using the high-pressure gas flow as power through the cutting mechanism 6, the high-pressure gas can be introduced into the dust suction mechanism 5 through the connecting gas pipe 607 and the diversion gas pipe 608, and the working power is provided for the dust suction mechanism 5 through the gas flow, so that the gas resources are fully used.

As a preferred embodiment of the present invention, there are two rotating motors 403, the first normally open switch 306 and the second normally open switch 307 are electrically connected through an internal conductive wire, and the first normally open switch 306 and the second normally open switch 307 are electrically connected through an external starting switch rotating motor 403, so that the synchronous starting of the two rotating motors 403 can be realized through this structure, and the rotating motors 403 cannot be started when the first normally open switch 306 and the second normally open switch 307 are in a normal state, thereby improving the safety performance of the device.

As a preferred embodiment of the invention, one end of the air inlet pipe 604 far away from the lifting box 603 penetrates through the top end of the cutting cabin 101 to be connected with an external air pump, one end of the branch air pipe 608 far away from the connecting air pipe 607 is connected with the air delivery hole 103, and the air delivery hole 103 penetrates into the equipment box 1 to be connected with the top end of the inner wall of the air cabin 105.

As a preferred embodiment of the present invention, the first gear 611 and the second gear 612 are engaged with each other, the number of teeth of the first gear 611 is greater than the number of teeth of the second gear 612, the first gear 611 can drive the second gear 612 to rotate, and the second gear 612 can rotate several turns when the first gear 611 rotates one turn, so that the high-speed rotation of the cutting blade 606 can be realized through the structure.

As a preferred embodiment of the invention, a plurality of curved arc-shaped blades 609 are arranged, the plurality of curved arc-shaped blades 609 are uniformly distributed on the side surface of the outer wall of the first rotating shaft 610 by taking the first rotating shaft 610 as the center, the outer wall of one side, away from the first rotating shaft 610, of the curved arc-shaped blades 609 is attached to the inner wall of the rotating cabin 6031, and by the structure, high-pressure gas can push the curved arc-shaped blades 609 to rotate when entering the rotating cabin 6031, so that the rotation of the first rotating shaft 610 is realized.

The working principle of the invention is as follows: when the ore electrical cutting equipment is used, the cutting cabin 101 is provided with a cabin door, ores to be cut are placed on the lifting platform 301 after the cabin door is opened, then the cabin door can be closed to carry out equipment operation through an external control button, the center line position of the ores is positioned below the center line of the matrix flexible clamp 406 at the moment, the first hydraulic push rod 302 can be started, the first hydraulic push rod 302 can push the lifting platform 301, the first telescopic platform 303 and the second telescopic platform 304 to synchronously move upwards, the ore height can be aligned with the height of the matrix flexible clamp 406 through the operation so as to quickly fix the ores, the first hydraulic push rod 302 can be stopped to operate when the ores are lifted to a proper height, the first normally open switch 306 and the second normally open switch 307 are in an unstressed normally open state, namely, the rotating motor 403 cannot be started to operate at the normal open state, and then the two clamping push rods 404 are synchronously started to operate, the clamping push rod 404 can push the first movable block 401 and the second movable block 402 to be close to each other, so that the matrix flexible clamp 406 is in contact with ores and can be extruded mutually, the ores can be fixed at the middle position of the clamping push rod through the two matrix flexible clamps 406, the matrix flexible clamp 406 can adapt to the uneven surface of the ores, the fixed clamping of the ores is firmer, the first telescopic table 303 and the second telescopic table 304 can be squeezed to shrink towards the inside of the telescopic groove 3011 in the process, the equipment can adapt to the fixation and cutting of the ores with different sizes through the structure, the second hydraulic push rod 601 and an external air pump can be started after the ores are fixed, the external air pump can generate high-pressure gas and transmit the high-pressure gas to the rotary cabin 6031 through the air inlet pipe, and then the high-pressure gas flows into the air cabin 105 through the air outlet hole, the connecting air pipe 607, the flow dividing air pipe 608 and the air delivery hole 103, and the side surface of the outer wall of the curved, therefore, the high-pressure gas can drive the curved arc-shaped blade 609 to rotate in the flowing process of the rotating chamber 6031, the curved arc-shaped blade 609 can drive the first gear 611 to rotate through the first rotating shaft 610, the first gear 611 can drive the second gear 612 to rotate, the second gear 612 can drive the second rotating shaft 613 and the cutting blade 606 to rotate, the second hydraulic push rod 601 can push the lifting box 603 and the cutting blade 606 rotating at high speed to move downwards through the connecting rod 602, the cutting operation of ore can be carried out through the contact of the cutting blade 606 rotating at high speed and the ore, dust generated in the ore cutting process can be scattered in the cutting chamber 101, meanwhile, the high-pressure gas entering the gas chamber 105 can be discharged through the exhaust hole 1051, the gas flow can drive the arc-shaped blade 503 to rotate when passing through the exhaust hole 1051, the arc-shaped blade 503 can drive the dust-absorbing blade 501 to rotate, and the negative pressure suction can be generated in the dust-collecting chamber 104, the suction force can suck the dust in the cutting cabin 101 into the dust collecting cabin 104 through the grid plate 505, the dust accumulated in the dust collecting cabin 104 can be intensively cleaned by opening the dust cleaning cabin door 2, when large-volume ore is cut, because the size of the cutting blade 606 is limited, the ore cannot be completely cut once, the ore needs to be rotated so as to be cut from the other side, at the moment, the second hydraulic push rod 601 can be operated reversely to restore the cutting blade 606 to the original position, then the first hydraulic push rod 302 is operated reversely to move the lifting platform 301 downwards to the original position, at the moment, the lifting platform 301 can extrude the first normally open switch 306 and the second normally open switch 307, the first normally open switch 306 and the second normally open switch 307 are in a closed state, namely, the rotating motor 403 can be started to operate at the moment, the two rotating motors 403 can realize the ore overturning operation by driving the matrix flexible clamp 406 to rotate after synchronous operation, can rise elevating platform 301 and make its and ore laminating after the ore upset is accomplished to take place the phenomenon that drops after avoiding the ore cutting to accomplish, later can drive cutting piece 606 downstream through No. two hydraulic pressure push rod 601 and cut the ore, can realize the quick cutting operation of ore through the operation of above a plurality of steps.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention are equivalent to or changed within the technical scope of the present invention.

Claims

1. The utility model provides an ore electrical cutting equipment, includes equipment box (1), elevating system (3), fixture (4), dust absorption mechanism (5), cutting mechanism (6), its characterized in that, outer wall one side of equipment box (1) is provided with cutting cabin (101), dust removal hatch door (2) are located the both ends of cutting cabin (101) below, the inner wall bottom of cutting cabin (101) is provided with sliding tray (102), gas transmission hole (103) are located one side at sliding tray (102) both ends, the inner wall bottom of sliding tray (102) is provided with spacing grooved rail (1021), the below that the inside of equipment box (1) is located gas transmission hole (103) is provided with gas cabin (105), the inside one end that is located gas cabin (105) of equipment box (1) is provided with collection dirt cabin (104), the one end that collection dirt cabin (104) was kept away from in gas cabin (105) is provided with exhaust hole (1051) through to equipment box (1) outer wall ) The cutting machine is characterized in that the lifting mechanism (3), the clamping mechanism (4) and the cutting mechanism (6) are located inside the cutting cabin (101), the lifting mechanism (3) and the clamping mechanism (4) are all sleeved with the inner wall of the sliding groove (102), the clamping mechanism (4) is located at two ends of the lifting mechanism (3), the cutting mechanism (6) is located above the lifting mechanism (3) and penetrates through the top end of the equipment box (1), and the dust collection mechanism (5) is located inside the dust collection cabin (104) and the air cabin (105).

2. The ore electrical cutting equipment according to claim 1, wherein the lifting mechanism (3) comprises a lifting platform (301), a first hydraulic push rod (302), a first telescopic platform (303), a second telescopic platform (304), a telescopic spring (305), a first normally open switch (306) and a second normally open switch (307), the lifting platform (301), the first telescopic platform (303) and the second telescopic platform (304) are mutually sleeved with the inner wall of the sliding groove (102), the first telescopic platform (303) and the second telescopic platform (304) are respectively positioned at two ends of the lifting platform (301), a telescopic groove (3011) is arranged inside the lifting platform (301), the telescopic spring (305) is positioned inside the telescopic groove (3011), one end of the first telescopic platform (303) and the second telescopic platform (304) close to each other penetrates through the inside of the telescopic groove (3011) and is respectively attached to two ends of the telescopic spring (305), the output of a hydraulic push rod (302) and the bottom fixed connection of elevating platform (301), a hydraulic push rod (302) run through the bottom of sliding tray (102) to the inside of equipment box (1), expanding spring (305), No. one normally open switch (306) are located the below of elevating platform (301) and fixed mounting to the inner wall bottom of sliding tray (102), expanding spring (305), No. one normally open switch (306) are located the both ends of a hydraulic push rod (302) respectively.

3. The ore electrical cutting equipment according to claim 2, wherein the clamping mechanism (4) comprises a first movable block (401), a second movable block (402), a rotating motor (403), a clamping push rod (404), a limiting slide block (405), a matrix flexible clamp (406) and a rotating bearing (407), the bottom ends of the first movable block (401) and the second movable block (402) are sleeved with the inner wall of the sliding groove (102), the first movable block (401) and the second movable block (402) are respectively located at one ends, far away from the lifting platform (301), of the first telescopic platform (303) and the second telescopic platform (304), the limiting slide block (405) is located at the bottom ends of the first movable block (401) and the second movable block (402) and is sleeved with the inner wall of the limiting groove rail (1021), and the matrix flexible clamp (406) is located at the first movable block (401), No. two movable block (402) one end that is close to each other, the one end that rotates motor (403), centre gripping push rod (404) and be located movable block (401), No. two movable block (402) and keep away from each other, centre gripping push rod (404) are located the below of rotating motor (403), the bottom fixed connection of centre gripping push rod (404) and cutting cabin (101), the inside of rotating motor (403), No. two movable block (402) is provided with rotates cabin (408), rolling bearing (407) are located the inside of rotating cabin (408), the one end of matrix flexible clamp (406) is run through to the inner wall that rotates cabin (408) inside and rolling bearing (407) and is cup jointed each other, the output that rotates motor (403) runs through to rotating cabin (408) inside and rolling bearing (407) is connected.

4. The ore electrical cutting equipment according to claim 1, wherein the dust suction mechanism (5) comprises dust suction blades (501), a transmission shaft (502), arc-shaped blades (503), a dust screen (504) and a grid plate (505), the dust suction blades (501) are positioned inside the air chamber (105), the transmission shaft (502) is positioned inside the air chamber (105), the arc-shaped blades (503) and the dust screen (504) are sleeved with the inner wall of the exhaust hole (1051), two ends of the dust suction blades (501) respectively penetrate through the dust collection chamber (104), the exhaust hole (1051) and are connected with the dust suction blades (501) and the arc-shaped blades (503), the dust screen (504) is positioned at one end of the arc-shaped blades (503) far away from the dust suction blades (501), one end of the dust collection chamber (104) far away from the air chamber (105) penetrates through the inside the sliding groove (102) and is connected with two ends of the inner wall of the sliding groove (102), the grid plate (505) is positioned at the contact position of the dust collecting cabin (104) and the sliding groove (102).

5. The ore electrical cutting equipment according to claim 1, wherein the cutting mechanism (6) comprises a second hydraulic push rod (601), a connecting rod (602), a lifting box (603), an air inlet pipe (604), a protective baffle (605), a cutting blade (606), a connecting air pipe (607), a flow dividing air pipe (608), a curved arc-shaped blade (609), a first rotating shaft (610), a second gear (612) and a second rotating shaft (613), the second hydraulic push rod (601) is positioned at the top end of the equipment box (1), the connecting rod (602), the lifting box (603) and the air inlet pipe (604) are positioned inside the cutting cabin (101), the lifting box (603) is positioned above the lifting mechanism (3), the connecting rod (602) and the air inlet pipe (604) are positioned at the top of the lifting box (603), and the bottom end of the second hydraulic push rod (601) penetrates through the inside the cutting cabin (101) to be connected with the top end of the connecting rod (602), protection baffle (605), connecting trachea (607) are located the both ends of lifting box (603) respectively, cutting piece (606) are located protection baffle (605) and keep away from the one end of lifting box (603), reposition of redundant personnel trachea (608) are located connecting trachea (607) and keep away from the one end of lifting box (603), the inside of lifting box (603) is provided with rotatory cabin (6031), transmission cabin (6032), venthole (6033), transmission cabin (6032) are located the one end of rotatory cabin (6031), venthole (6033) are located the inner wall bottom of rotatory cabin (6031) and run through to the outer wall of lifting box (603) and are connected trachea (607), curved surface arc blade (609), a axis of rotation (610) are located the inside of rotatory cabin (6031), curved surface arc blade (609) are located the outer wall side of a axis of rotation (610), a gear (611) has, No. two gear (612), No. two axis of rotation (613) are located inside transmission cabin (6032), No. two gear (612) are located gear (611) one side, the one end of No. two axis of rotation (613) cup joints with the inner wall of No. two gear (612) each other, the one end of a axis of rotation (610) is run through to transmission cabin (6032) inside and the inner wall of a gear (611) cup joints with each other, the one end that No. two gear (612) were kept away from to No. two axis of rotation (613) runs through transmission cabin (6032), protection baffle (605) and the one end and the cutting piece (606) of protection baffle (605) cup joint with each other.

6. An electric ore cutting device according to claim 3, wherein the number of the rotating motors (403) is two, the first normally open switch (306) and the second normally open switch (307) are electrically connected through internal wires, and the first normally open switch (306) and the second normally open switch (307) are electrically connected through an external starting switch rotating motor (403).

7. The electrical ore cutting equipment as claimed in claim 5, characterized in that one end of the air inlet pipe (604) far away from the lifting box (603) penetrates through the top end of the cutting chamber (101) to be connected with an external air pump, one end of the diversion air pipe (608) far away from the connecting air pipe (607) is connected with the air delivery hole (103), and the air delivery hole (103) penetrates into the equipment box (1) to be connected with the top end of the inner wall of the air chamber (105).

8. An electric ore cutting apparatus according to claim 5, wherein the first gear (611) and the second gear (612) are meshed with each other, and the number of teeth of the first gear (611) is larger than that of the second gear (612).

9. The electrical ore cutting equipment as claimed in claim 6, characterized in that the number of the cambered arc-shaped blades (609) is provided with a plurality of cambered arc-shaped blades, the cambered arc-shaped blades (609) are uniformly distributed on the side surface of the outer wall of the first rotating shaft (610) by taking the first rotating shaft (610) as a center, and the outer wall of one side of the cambered arc-shaped blades (609) far away from the first rotating shaft (610) is attached to the inner wall of the rotating cabin (6031).