CN111871515B

CN111871515B - Ore waste treatment device

Info

Publication number: CN111871515B
Application number: CN202010753846.8A
Authority: CN
Inventors: 王青波
Original assignee: Huidong Jiahua Materials Co ltd
Current assignee: Huidong Jiahua Materials Co.,Ltd.
Priority date: 2020-07-30
Filing date: 2020-07-30
Publication date: 2021-11-12
Anticipated expiration: 2040-07-30
Also published as: CN111871515A

Abstract

The invention relates to the field of ores, in particular to an ore waste treatment device. The invention aims to provide an ore waste treatment device. An ore waste treatment device comprises a bottom working frame plate, a first supporting high leg column, a rolling and crushing mechanism, a secondary intercepting and crushing mechanism, a separating disc grinding mechanism, an operation control screen, an integrating strip frame and the like; one side of the upper part of the bottom working frame plate is connected with the first supporting high leg column and the second supporting high leg column in sequence. The invention realizes the high-efficiency crushing of the waste leftover materials left after cutting of granite, and simultaneously carries out secondary crushing after intercepting on large stones leaked in primary crushing, separates long strip-shaped stones with qualified width but longer width, carries out double-side disc grinding on the crushed stones with edges, and polishes and removes the edges to obtain round granite stones for paving.

Description

Ore waste treatment device

Technical Field

The invention relates to the field of ores, in particular to an ore waste treatment device.

Background

Ore refers to a collection of minerals from which useful components can be extracted or which themselves have some property that can be exploited. Can be divided into metal mineral and nonmetal mineral. The unit content of useful components (elements or minerals) in the ore is called ore grade, the precious metal ore such as gold and platinum is expressed in grams/ton, and other ores are expressed in percentage.

Granite is a structural rock formed by raising volcanic eruption lava to the surface layer of crust under the condition of melting under a certain pressure, the magma is not sprayed out of the ground, but is slowly cooled and solidified under the ground, and is a deep acidic igneous rock, modern road construction is usually carried out by using stones and concrete to lay certain paths, such as field roads and park roads, cobblestones are usually adopted to lay, part of the granite stones are adopted, most of the granite ores are cut into stone squares, if the granite ores are crushed to obtain the stones, the cost is higher, therefore, a plurality of leftover materials are usually utilized after the granite is cut, but in the prior art, because the granite leftover materials are usually in sheet shape, irregular shapes such as sheet shape and the like, manual crushing is often needed, and the crushing rate of the irregular shape leftover materials is lower when the granite leftover materials are crushed, the more edges and corners exist in the garrulous stone that obtains simultaneously, and then lead to granite cutting corner waste material when carrying out the breakage, have a large amount of irregular ores such as rectangular form that can't carry out broken handle, can't obtain the utilization, granite ore waste material is because the slice strip is more simultaneously, can have comparatively sharp edges and corners on the stone surface that the cutting obtained, and this type of stone is used for laying the road surface, can lead to there being sharp-pointed arch in the road surface, can harm the problem of the sole of the crowd of walking.

Therefore, there is a need to develop an ore waste treatment apparatus to overcome the above problems.

Disclosure of Invention

The invention aims to overcome the defects that granite leftover materials are often in irregular shapes such as sheets and long strips and are often required to be manually crushed, the breakage rate of the irregular-shaped leftover materials is low when the granite leftover materials are crushed, meanwhile, more edges and corners exist in the obtained crushed stones, and further, a large amount of irregular ores such as long strips and the like which cannot be crushed exist in the granite cutting leftover waste materials when the granite cutting leftover materials are crushed cannot be utilized, meanwhile, the granite ore waste materials are more in sheet strips, sharper edges and corners exist on the surfaces of the stones obtained by cutting, and the stones are used for paving a road surface, so that the road surface has sharp bulges and can damage soles of walking people.

The invention is achieved by the following specific technical means:

an ore waste treatment device comprises a bottom working frame plate, a first supporting high leg column, a second supporting high leg column, a high-rise working frame plate, a side supporting window plate, a rolling and crushing mechanism, a secondary intercepting and crushing mechanism, a separating disc grinding mechanism, an operation control screen and an integrating strip frame; one side above the bottom working frame plate is sequentially connected with the first supporting high leg column and the second supporting high leg column, and the other side above the bottom working frame plate is connected with the separating disc grinding mechanism; the upper part of the bottom working frame plate is connected with the integrating strip frame; the lower part of the high-rise working frame plate is sequentially connected with a first supporting high foot column and a second supporting high foot column; the high-rise working frame plate is connected with the operation control screen; the high-rise working frame plate is connected with the integrating strip frame; one side above the high-rise working frame plate is welded with the lateral supporting window plate, and the other side above the high-rise working frame plate is connected with the separating disc grinding mechanism; the side supporting window plate is connected with the separating disc grinding mechanism; the side supporting window plate is connected with the secondary intercepting and fragmenting mechanism; the upper part of the secondary interception and fragmentation mechanism is connected with the rolling and crushing mechanism; the secondary interception fragmentation mechanism is connected with the integration strip frame;

the rolling and crushing mechanism comprises a first power motor, a first motor plate, a first rotating shaft rod, a first driving wheel, a first flat gear, a second flat gear, a first rolling roller, a crushing cabin, a second rolling roller, a first fixed frame plate and a second fixed frame plate; the lower part of the first power motor is connected with a first motor plate through a bolt; the output shaft of the first power motor is rotationally connected with the first rotating shaft rod; the outer surface of the first rotating shaft rod is sleeved with the first driving wheel; the first rotating shaft rod is in rotating connection with the first flat gear; the first flat gear is meshed with the second flat gear; the axle center of the first flat gear is rotationally connected with the first rolling roller; the axle center of the second flat gear is rotationally connected with the second rolling roller; the inner side of the crushing cabin is sequentially connected with a first rolling roller and a second rolling roller; one side of the crushing cabin is connected with the first fixed frame plate, and the other side of the crushing cabin is connected with the second fixed frame plate; the first motor plate is connected with the secondary interception and fragmentation mechanism; the lower part of the first driving wheel is connected with a secondary intercepting and smashing mechanism; the first fixed frame plate and the second fixed frame plate are both connected with the secondary intercepting and fragmenting mechanism; the outer surface of the first rotating shaft rod is connected with the secondary intercepting and crushing mechanism;

the secondary intercepting and fragmenting mechanism is connected with the secondary intercepting and fragmenting mechanism and comprises a second driving wheel, a second rotating shaft rod, a plum blossom vibrating wheel, a first bearing frame plate, a second bearing frame plate, a driving arc strip, a first connecting strip plate, an intercepting mechanism, a first sliding block, a first rectangular chute plate, a first rebound spring, a first collecting strip plate, a second collecting plate, a second buffer moving mechanism, a third collecting plate, a second sliding block, a second rectangular chute plate and a second rebound spring; the inner surface of the second driving wheel is sleeved with the second rotating shaft rod; one side of the second rotating shaft rod is inserted into the second gathering plate through a bearing, and the other side of the second rotating shaft rod is rotatably connected with the plum blossom vibrating wheel; one side of the outer surface of the plum blossom vibration wheel is sleeved with the second bearing frame plate, and the other side of the outer surface of the plum blossom vibration wheel is sleeved with the first bearing frame plate; the plum blossom vibration wheel is in transmission connection with the transmission arc-shaped strip; welding the transmission arc-shaped strip and the first connecting strip plate; the upper part of the first linking slat is connected with the interception mechanism; the lower part of the first linking batten is sequentially spliced with the first sliding block and the second sliding block; the outer surface of the first sliding block is in sliding connection with the first rectangular sliding groove plate; the outer surface of the second sliding block is in sliding connection with the second rectangular sliding groove plate; one side of the first rebound spring is connected with the first sliding block, and the other side of the first rebound spring is connected with the first rectangular sliding chute plate; one side of the second rebound spring is connected with the second sliding block, and the other side of the second rebound spring is connected with the second rectangular chute plate; the upper part of the first collective slat is connected with a first rectangular chute board and a second rectangular chute board in sequence; the third collecting plate is sequentially connected with the first collecting strip plate and the second buffer moving mechanism; the upper part of the second buffer moving mechanism is connected with the interception mechanism; the lower part of the interception mechanism is connected with the first collection batten; the interception mechanism is connected with the second gathering plate; the upper part of the third collecting plate is connected with the second collecting plate; the second gathering plate is connected with the intercepting mechanism; the second collecting plate is sequentially connected with the first motor plate and the first rotating shaft rod; the second buffer moving mechanism is connected with the first fixed frame plate; the first collective slat is connected with the second fixed frame plate; the third collecting plate is connected with the integrating strip frame; the first collective slat and the second buffer moving mechanism are connected with the side supporting window plates; the upper part of the second driving wheel is connected with the first driving wheel; the second buffer moving mechanism is connected with the separating disc grinding mechanism; the third collecting plate is connected with the separating disc grinding mechanism;

the separating disc grinding mechanism comprises a second power motor, a third spur gear, a third driving wheel, a fourth spur gear, a first grinding disc, a fourth driving wheel, a fifth spur gear, a second grinding disc, a sixth spur gear, a first gear rack plate, a seventh spur gear, a first electric sliding seat, a second electric sliding seat, a fourth collecting plate, a blanking collecting cabin, a fixed cabin plate, a separating screen, a second connecting plate and a waste collecting hopper; the output shaft of the second power motor is rotationally connected with the third spur gear; the third flat gear is meshed with the fourth flat gear; the axle center of the third flat gear is rotationally connected with a third transmission wheel; the axle center of the fourth flat gear is rotationally connected with the first grinding disc; the outer ring surface of the third driving wheel is in transmission connection with the fourth driving wheel through a belt; the axle center of the fourth transmission wheel is rotationally connected with the fifth flat gear; a second grinding disc is arranged above the first grinding disc; the axle center of the second grinding disc is rotationally connected with the sixth flat gear; the axis of the sixth flat gear is inserted into the first gear frame plate through a bearing; the sixth flat gear is meshed with the seventh flat gear; the seventh flat gear shaft center is inserted with the first gear rack plate through a bearing; the first gear frame plate is sequentially connected with the first electric sliding seat and the second electric sliding seat through bolts; the first electric sliding seat is connected with the first electric sliding rail in a sliding manner; the second electric sliding seat is in sliding connection with the second electric sliding rail; the upper part of the fourth collecting plate is sequentially connected with the first electric slide rail and the second electric slide rail; a blanking collecting cabin is arranged above the first grinding disc; welding the blanking collecting cabin and the fixed cabin plate; a separation screen is arranged above the blanking collection cabin; one side of the separation screen is connected with a waste collecting hopper; welding the lower part of the waste collecting hopper with a second connecting strip plate; the second linking strip plate is connected with the side supporting window plate; the separating screen is sequentially connected with the second buffer moving mechanism and the third collecting plate; the lower part of the second power motor is connected with the bottom working frame plate; the axle center of the fourth flat gear is connected with the bottom working frame plate; the lower part of the fourth collecting plate is connected with the bottom working frame plate; the axle center of the fourth driving wheel is connected with the bottom working frame plate; the fixed cabin plate is sequentially connected with the high-rise working frame plate and the side supporting window plate;

the intercepting mechanism comprises a first inclined intercepting plate, a first cylindrical fixed frame, a second inclined intercepting plate, a protective bending plate, a first electric push rod, a second electric push rod, a triangular prism impact block and an inverted V-shaped frame; one side of the first inclined interception plate is connected with the first cylindrical fixed frame, and the other side of the first inclined interception plate is connected with the second cylindrical fixed frame; one side of the second inclined interception plate is connected with the first cylindrical fixed frame, and the other side of the second inclined interception plate is connected with the second cylindrical fixed frame; a protective bending plate is arranged below the first cylindrical fixing frame; the lower part of the protective bending plate is sequentially connected with a first electric push rod and a second electric push rod; the upper part of the triangular prism impact block is sequentially connected with a first electric push rod and a second electric push rod; the inverted V-shaped frame is connected with the protective bending plate; the protective bending plate is connected with the second gathering plate; the lower part of the inverted V-shaped frame is connected with the first collective lath and the second buffer moving mechanism in turn.

Further, the distance between the lowest end of the gap space formed between the first inclined interception plate and the second inclined interception plate is the maximum diameter allowed by broken stones at the minimum distance.

Furthermore, an electric rotating shaft switch door is arranged at an outlet below the blanking collecting cabin.

Further, the upper surface of the first grinding disc and the lower surface of the second grinding disc are provided with uniform dome bulges.

Furthermore, a notch is formed in one side, close to the blanking collecting cabin, of the edge baffle of the first grinding disc.

Further, the second buffer moving mechanism has the same structure as the first linking slat, the first slider, the first rectangular chute plate, the first rebound spring, the first collective slat, the second slider, the second rectangular chute plate and the second rebound spring, and is bilaterally symmetrical to the first linking slat, the first slider, the first rectangular chute plate, the first rebound spring, the first collective slat, the second slider, the second rectangular chute plate and the second rebound spring with the intercepting mechanism as a symmetrical axis.

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

the problems that the granite leftover materials are usually in irregular shapes such as sheets and long strips and need to be manually crushed, the crushing rate of the irregular-shaped leftover materials is low when the granite leftover materials are crushed, and meanwhile, more edges and corners exist in the obtained crushed stones, so that a large amount of irregular ores such as long strips and the like which cannot be crushed exist in the granite cutting leftover waste materials when the granite cutting leftover materials are crushed cannot be utilized, and meanwhile, the granite ore waste materials are more in sheet strips, so that the surfaces of the stones obtained by cutting have sharp edges and corners, and the stones are used for paving pavements can cause sharp bulges on the pavements and can damage soles of walking crowds are solved;

the grinding and crushing mechanism, the secondary intercepting and crushing mechanism and the separating disc grinding mechanism are designed, when in use, leftover materials cut by granite, namely waste stone materials, are firstly added into the grinding and crushing mechanism, firstly, the leftover materials are crushed to obtain stones with smaller particle sizes, then, crushed mixtures enter the secondary intercepting and crushing mechanism to be primarily screened, namely, stones with larger volume and larger particle sizes which are not reduced in the crushing process are separated, then, the secondary intercepting and crushing mechanism carries out secondary crushing treatment on the stones to enable the particle sizes to meet the standard, then, the mixtures enter the separating disc grinding mechanism to intercept and collect some long-strip-shaped stones which are not separated, then, the separating disc grinding mechanism carries out disc grinding operation on the stones with qualified particle sizes to grind the edges and corners of the stones, so that the surfaces of the stones are rounded;

realized the abandonment leftover bits that leave over behind the high-efficient broken granite cutting is accomplished, carried out the secondary fragmentation after the interception to the bold stone that once breaks and leak simultaneously, with the qualified but longer rectangular shape stone of width separation and carry out two-sided dish mill with the stone that obtains the fragmentation to have the edges and corners, polish with its edges and corners and get rid of, obtain the effect of mellow and smooth granite stone in order to be used for the road paving.

Drawings

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

fig. 2 is a schematic view of a first three-dimensional structure of the rolling crushing mechanism of the invention;

fig. 3 is a schematic diagram of a second three-dimensional structure of the rolling crushing mechanism of the invention;

FIG. 4 is a schematic perspective view of a secondary intercepting and reducing mechanism according to the present invention;

FIG. 5 is a schematic view of a first perspective structure of the separating disc grinding mechanism of the present invention;

FIG. 6 is a second perspective view of the split disc grinding mechanism of the present invention;

FIG. 7 is a schematic view of a first perspective structure of the intercepting mechanism of the present invention;

FIG. 8 is a schematic view of a second perspective view of the intercepting mechanism of the present invention;

FIG. 9 is a schematic view of a first polishing disk according to the present invention.

The labels in the figures are: 1-a bottom working frame plate, 2-a first supporting high stilt, 3-a second supporting high stilt, 4-a high working frame plate, 5-a side supporting window plate, 6-a rolling and crushing mechanism, 7-a secondary intercepting and crushing mechanism, 8-a separating disc grinding mechanism, 9-an operation control screen, 10-an integrated strip frame, 601-a first power motor, 602-a first motor plate, 603-a first rotating shaft rod, 604-a first driving wheel, 605-a first flat gear, 606-a second flat gear, 607-a first rolling roller, 608-a crushing cabin, 609-a second rolling roller, 6010-a first fixed frame plate, 6011-a second fixed frame plate, 701-a second driving wheel, 702-a second rotating shaft, 703-a quincuncial vibrating wheel, 704-a first bearing frame plate, 705-a second bearing frame plate, 706-a transmission arc bar, 707-a first engagement strip, 708-an interception mechanism, 709-a first sliding block, 7010-a first rectangular chute plate, 7011-a first rebound spring, 7012-a first collective strip, 7013-a second collective plate, 7014-a second buffer moving mechanism, 7015-a third collective plate, 7016-a second sliding block, 7017-a second rectangular chute plate, 7018-a second rebound spring, 801-a second motor, 802-a third gear, 803-a third transmission wheel, 804-a fourth gear, 805-a first grinding disc, 806-a fourth transmission wheel, 807-a fifth gear, 808-a second grinding disc, 809-a sixth gear, 8010-a first gear frame plate, 8011-a seventh gear, 8012-first electric sliding base, 8013-first electric sliding base, 8014-second electric sliding base, 8015-second electric sliding base, 8016-fourth gathering plate, 8017-blanking collecting cabin, 8018-fixed cabin plate, 8019-separating screen, 8020-second joining strip plate, 8021-waste collecting hopper, 70801-first inclined baffle, 70802-first cylindrical fixed frame, 70803-second cylindrical fixed frame, 70804-second inclined baffle, 70805-protective bending plate, 70806-first electric push rod, 70807-second electric push rod, 70808-triangular prism impact block, 70809-inverted V frame.

Detailed Description

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

Examples

An ore waste treatment device is shown in figures 1-9 and comprises a bottom working frame plate 1, a first supporting high column 2, a second supporting high column 3, a high working frame plate 4, a side supporting window plate 5, a rolling crushing mechanism 6, a secondary intercepting and crushing mechanism 7, a separating disc grinding mechanism 8, an operation control screen 9 and an integrating bar frame 10; one side above the bottom working frame plate 1 is sequentially connected with a first supporting high leg column 2 and a second supporting high leg column 3, and the other side above the bottom working frame plate 1 is connected with a separating disc grinding mechanism 8; the upper part of the bottom working frame plate 1 is connected with an integrated strip frame 10; the lower part of the high-rise working frame plate 4 is sequentially connected with a first supporting high leg column 2 and a second supporting high leg column 3; the high-rise working frame plate 4 is connected with an operation control screen 9; the high-rise working frame plate 4 is connected with the integrating strip frame 10; one side above the high-rise working frame plate 4 is welded with the lateral supporting window plate 5, and the other side above the high-rise working frame plate 4 is connected with the separating disc grinding mechanism 8; the side supporting window plate 5 is connected with a separating disc grinding mechanism 8; the side supporting window plates 5 are connected with a secondary intercepting and smashing mechanism 7; the upper part of the secondary intercepting and crushing mechanism 7 is connected with the rolling and crushing mechanism 6; the secondary interceptor reducing mechanism 7 is connected to the integral strip frame 10.

When the ore waste treatment device is used, the device is stably fixed on a working plane, then a power supply is connected externally, the operation control screen 9 is manually opened, then the operation control screen 9 controls and connects a power system driving device in the device to operate, firstly, leftover materials cut by granite, namely waste stone materials, are added into the rolling and crushing mechanism 6, firstly, the leftover materials are crushed to obtain stones with smaller particle sizes, then, the crushed mixture enters the secondary intercepting and crushing mechanism 7 to be primarily screened, namely, stones with larger sizes and without reduced particle sizes in the crushing process are separated, then, the secondary intercepting and crushing mechanism 7 carries out secondary crushing treatment on the stones to ensure that the particle sizes of the stones meet the standard, then, the mixture enters the separating disc grinding mechanism 8 to collect some long-strip-shaped unseparated stones, then separating disk mill 8 carries out the disk mill operation to the qualified stone of particle diameter, grind the edges and corners of stone, make its surface become mellow and full, the abandonment leftover bits of leaving over after having realized the cutting of high-efficient broken granite, carry out the secondary fragmentation after the interception to the bold stone that once breaks and misses simultaneously, separate the qualified but longer rectangular shape stone of width and carry out the two-sided disk mill with the stone that the fragmentation obtained has the edges and corners, polish its edges and corners and get rid of, obtain the effect of mellow and full granite stone in order to be used for the road paving.

The crushing mechanism 6 comprises a first power motor 601, a first motor plate 602, a first rotating shaft rod 603, a first driving wheel 604, a first pinion 605, a second pinion 606, a first crushing roller 607, a crushing cabin 608, a second crushing roller 609, a first fixed frame plate 6010 and a second fixed frame plate 6011; the lower part of the first power motor 601 is connected with a first motor plate 602 through bolts; an output shaft of the first power motor 601 is rotatably connected with the first rotating shaft rod 603; the outer surface of the first rotating shaft 603 is sleeved with the first driving wheel 604; the first rotating shaft 603 is in rotational connection with the first spur gear 605; the first pinion 605 meshes with the second pinion 606; the axis of the first flat gear 605 is rotationally connected with the first rolling roller 607; the axle center of the second flat gear 606 is rotationally connected with the second rolling roller 609; the inner side of the crushing cabin 608 is connected with a first rolling roller 607 and a second rolling roller 609 in turn; one side of the crushing chamber 608 is connected with a first fixed frame plate 6010, and the other side of the crushing chamber 608 is connected with a second fixed frame plate 6011; the first motor plate 602 is connected with the secondary intercepting and smashing mechanism 7; the lower part of the first driving wheel 604 is connected with a secondary intercepting and smashing mechanism 7; the first fixed frame plate 6010 and the second fixed frame plate 6011 are both connected with the secondary intercepting and fragmenting mechanism 7; the outer surface of the first rotating shaft 603 is connected with the secondary intercepting and reducing mechanism 7.

First power motor 601 power is firstly switched on through operation control panel 9, then first power motor 601 drives first pivot pole 603 and rotates, and then first pivot pole 603 drives first drive wheel 604 and rotates, and simultaneously first pivot pole 603 drives first pinion 605 and rotates, and then first pinion 605 drives second pinion 606 and first rolling roller 607 and rotates, and then second pinion 606 drives second rolling roller 609 and rotates, and then second rolling roller 609 and first rolling roller 607 reverse rotation extrude to the centre, then add granite leftover bits into crushing cabin 608 inside, carry out the preliminary crushing of waste rock material, the fragmentation of granite cutting leftover bits has been accomplished.

The secondary intercepting and crushing mechanism 7 is connected with a second driving wheel 701, a second rotating shaft rod 702, a plum blossom vibrating wheel 703, a first bearing frame plate 704, a second bearing frame plate 705, a driving arc strip 706, a first connecting strip 707, an intercepting mechanism 708, a first sliding block 709, a first rectangular chute plate 7010, a first rebound spring 7011, a first collective strip 7012, a second collective plate 7013, a second buffer moving mechanism 7014, a third collective plate 7015, a second sliding block 7016, a second rectangular chute plate 7017 and a second rebound spring 7018; the inner surface of the second driving wheel 701 is sleeved with a second rotating shaft rod 702; one side of the second rotating shaft rod 702 is inserted into the second collecting plate 7013 through a bearing, and the other side of the second rotating shaft rod 702 is rotatably connected with the quincuncial vibration wheel 703; one side of the outer surface of the plum blossom vibration wheel 703 is sleeved with a second bearing frame plate 705, and the other side of the outer surface of the plum blossom vibration wheel 703 is sleeved with a first bearing frame plate 704; the plum blossom vibrating wheel 703 is in transmission connection with the transmission arc-shaped strip 706; the transmission arc-shaped strip 706 is welded with the first connecting strip 707; the upper part of the first connecting strip plate 707 is connected with the intercepting mechanism 708; the lower part of the first linking strip 707 is sequentially spliced with a first sliding block 709 and a second sliding block 7016; the outer surface of the first slider 709 is in sliding connection with the first rectangular chute plate 7010; the outer surface of the second sliding block 7016 is in sliding connection with a second rectangular chute plate 7017; one side of the first resilient spring 7011 is connected to the first slider 709, and the other side of the first resilient spring 7011 is connected to the first rectangular chute plate 7010; one side of a second rebound spring 7018 is connected with the second slider 7016, and the other side of the second rebound spring 7018 is connected with a second rectangular chute plate 7017; the upper part of the first collective batten 7012 is connected with a first rectangular chute plate 7010 and a second rectangular chute plate 7017 in sequence; the third collecting plate 7015 is connected to the first collecting slat 7012 and the second buffer moving mechanism 7014 in sequence; the upper part of the second buffer moving mechanism 7014 is connected with the interception mechanism 708; the lower part of the interception mechanism 708 is connected with a first collective batten 7012; the upper part of the third assembly plate 7015 is connected with a second assembly plate 7013; the second gathering plate 7013 is connected to the intercepting mechanism 708; the second collecting plate 7013 is connected to the first motor plate 602 and the first rotating shaft 603 in sequence; the second buffer moving mechanism 7014 is connected to the first fixed frame plate 6010; the first collective slat 7012 is connected to the second fixed frame 6011; the third integrated board 7015 is connected to the integrated bar frame 10; the first collective slat 7012 and the second cushioned movement mechanism 7014 are each connected to the side supporting louvers 5; the upper part of the second transmission wheel 701 is connected with a first transmission wheel 604; the second buffer moving mechanism 7014 is connected with the separating disc grinding mechanism 8; the third collecting plate 7015 is connected to the separate disc grinder mechanism 8.

Firstly, crushed stones in the rolling and crushing mechanism 6 fall from the crushing cabin 608 to the inside of the intercepting mechanism 708, meanwhile, the first driving wheel 604 drives the second driving wheel 701 to rotate, then the second driving wheel 701 drives the quincuncial vibration wheel 703 to rotate through the second rotating shaft rod 702, then each petal of the quincuncial vibration wheel 703 continuously touches the transmission arc-shaped strip 706 to cause high-frequency impact on the transmission arc-shaped strip 706 in contact therewith, further, the transmission arc-shaped strip 706 drives the first linking strip 707 and the whole intercepting mechanism 708 to vibrate, simultaneously, the first linking strip 707 drives the first sliding block 709 and the second sliding block 7016 to respectively slide in the first rectangular sliding chute plate 7010 and the second rectangular sliding chute plate 7017, simultaneously, the first sliding block 709 and the second sliding block 7016 respectively compress the first rebound spring 7011 and the second rebound spring 7018, and simultaneously, after the first rebound spring 7011 and the second rebound spring 7018 are compressed, elasticity is generated to connect and then drive the first sliding block 707 to reset, the high-frequency vibration that has so reciprocated realized interception mechanism 708 promptly, realized the vibration screening to the inside stone of interception mechanism 708 that drops, inside the qualified stone of particle diameter falls to separating disc grinding mechanism 8, and the inside secondary fragmentation that carries on of interception mechanism 708 is stayed to the unqualified fragmented stone of particle diameter, and then has accomplished the secondary interception fragmentation of broken stone.

The separating disc grinding mechanism 8 comprises a second power motor 801, a third flat gear 802, a third driving wheel 803, a fourth flat gear 804, a first grinding disc 805, a fourth driving wheel 806, a fifth flat gear 807, a second grinding disc 808, a sixth flat gear 809, a first gear rack plate 8010, a seventh flat gear 8011, a first electric slide seat 8012, a first electric slide rail 8013, a second electric slide seat 8014, a second electric slide rail 8015, a fourth gathering plate 8016, a blanking collecting cabin 8017, a fixed cabin plate 8018, a separating screen 8019, a second engaging plate 8020 and a waste collecting bucket 8021; an output shaft of the second power motor 801 is rotatably connected with the third spur gear 802; the third flat gear 802 meshes with the fourth flat gear 804; the axle center of the third gear 802 is rotationally connected with a third driving wheel 803; the axis of the fourth flat gear 804 is rotationally connected with the first grinding disc 805; the outer annular surface of the third driving wheel 803 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 fifth flat gear 807; a second grinding disc 808 is arranged above the first grinding disc 805; the axle center of the second grinding disc 808 is rotationally connected with a sixth flat gear 809; the axis of the sixth flat gear 809 is inserted into the first gear frame plate 8010 through a bearing; sixth spur gear 809 meshes with seventh spur gear 8011; the axle center of the seventh spur gear 8011 is inserted into the first gear frame plate 8010 through a bearing; the first gear rack plate 8010 is in turn bolted to the first electric slide 8012 and the second electric slide 8014; the first electric slide seat 8012 is slidably connected to the first electric slide rail 8013; the second electric slide seat 8014 is slidably connected to the second electric slide rail 8015; a first electric slide rail 8013 and a second electric slide rail 8015 are connected to the upper side of the fourth gathering plate 8016 in sequence; a blanking collecting chamber 8017 is arranged above the first grinding disc 805; the blanking collecting chamber 8017 is welded with the fixed chamber plate 8018; a separation screen 8019 is arranged above the blanking collection chamber 8017; one side of the separating screen 8019 is connected with the waste collecting hopper 8021; the lower part of the waste collecting hopper 8021 is welded with a second connecting strip plate 8020; the second tie strip 8020 is connected to the side supporting window panel 5; the separation screen 8019 is connected to the second buffer moving mechanism 7014 and the third collecting plate 7015 in this order; the lower part of the second power motor 801 is connected with the bottom working frame plate 1; the axle center of the fourth flat gear 804 is connected with the bottom working frame plate 1; the lower part of the fourth gathering plate 8016 is connected with the bottom working frame plate 1; the axle center of the fourth driving wheel 806 is connected with the bottom working frame plate 1; the fixed deck panel 8018 is in turn connected to the high-rise working frame plate 4 and the side support window panel 5.

Firstly, stones fall from the secondary intercepting and crushing mechanism 7 to the upper part of the separating screen 8019 in the separating disc grinding mechanism 8, then the stones meeting the requirement of the particle size fall from the lower part of the separating screen 8019 to the inner part of the blanking collecting chamber 8017, meanwhile, longer stones fall into the inner part of the waste collecting hopper 8021 to be collected, then an opening at the lower part of the blanking collecting chamber 8017 is opened under the control of the operation control screen 9, then the stones fall onto the upper part of the first grinding disc 805, then the second power motor 801 is switched on under the control of the operation control screen 9 to rotate, then the second power motor 801 drives the third flat gear 802 to rotate, then the third flat gear 802 drives the third driving wheel 803 to rotate, then the third driving wheel 803 drives the fourth driving wheel 806 to rotate, then the fourth driving wheel 806 drives the fifth flat gear 807 to rotate, and simultaneously the third flat gear 802 drives the fourth flat gear 804 to rotate, further, the fourth flat gear 804 drives the first grinding disc 805 to rotate, and at the same time, the first electric slide rail 8013 and the second electric slide rail 8015 are controlled to respectively drive the first electric slide seat 8012 and the second electric slide seat 8014 to move downwards, further the first electric slide seat 8012 and the second electric slide seat 8014 drive the first gear frame plate 8010 to move downwards, and move to a position where the seventh flat gear 8011 is engaged with the fifth flat gear 807, then the downward movement is stopped, then the fifth flat gear 807 drives the seventh flat gear 8011 to rotate, then the seventh flat gear 8011 drives the sixth flat gear 809 to rotate, then the sixth flat gear 809 drives the second grinding disc 808 to rotate, then the second grinding disc 808 and the first grinding disc 805 rotate in opposite directions, further the second grinding disc 808 and the first grinding disc 805 grind stones between them, further grind edges and corners of the surfaces of the stones, and obtain the stones with round surfaces, the grinding of the angular stones is completed.

The intercepting mechanism 708 includes a first inclined intercepting plate 70801, a first cylindrical fixed frame 70802, a second cylindrical fixed frame 70803, a second inclined intercepting plate 70804, a protective bending plate 70805, a first electric push rod 70806, a second electric push rod 70807, a triangular prism impact block 70808, and an inverted V-shaped frame 70809; one side of the first inclined interception plate 70801 is connected with a first cylindrical fixed frame 70802, and the other side of the first inclined interception plate 70801 is connected with a second cylindrical fixed frame 70803; one side of the second inclined interception plate 70804 is connected with the first cylindrical fixed frame 70802 and the other side of the second inclined interception plate 70804 is connected with the second cylindrical fixed frame 70803; a protective bending plate 70805 is arranged below the first cylindrical fixing frame 70802; the lower part of the protective bending plate 70805 is sequentially connected with a first electric push rod 70806 and a second electric push rod 70807; the upper part of the triangular prism impact block 70808 is sequentially connected with a first electric push rod 70806 and a second electric push rod 70807; the inverted V-shaped frame 70809 is connected with the protective bending plate 70805; the protective bending plate 70805 is connected with a second gathering plate 7013; the lower part of the inverted-V-shaped rack 70809 is connected with a first collective slat 7012 and a second buffer moving mechanism 7014 in turn.

The first inclined interception plate 70801 and the second inclined interception plate 70804 vibrate, then stones with qualified particle sizes fall from a gap between the first inclined interception plate 70801 and the second inclined interception plate 70804, unqualified stones are intercepted at the bottommost end of the gap between the first inclined interception plate 70801 and the second inclined interception plate 70804, then the operation control screen 9 controls the first electric push rod 70806 and the second electric push rod 70807 to drive the triangular prism impact block 70808 to downwards push out the intercepted stones for impact fragmentation, the stones fall from the gap between the first inclined interception plate 70801 and the second inclined interception plate 70804 after fragmentation, and secondary fragmentation of the stones with unqualified particle sizes is completed.

The minimum distance between the lowest ends of the gap spaces formed between the first inclined interception plate 70801 and the second inclined interception plate 70804 is the maximum diameter allowed by the crushed stones, so that the stones with unqualified grain sizes are intercepted at the bottom ends of the first inclined interception plate 70801 and the second inclined interception plate 70804.

An electric rotating shaft switch door is arranged at an outlet below the blanking collecting chamber 8017 so as to control the blanking of the crushed stones.

The upper surface of the first abrasive disk 805 and the lower surface of the second abrasive disk 808 are each provided with uniform dome protrusions to facilitate removal of the corners of the stone surface.

The first grinding plate 805 is provided with a notch along the side of the baffle plate close to the blanking collecting chamber 8017 to facilitate shoveling of the ground stones from above the first grinding plate 805.

The second buffer moving mechanism 7014 has the same structure as the first engaging slat 707, the first slider 709, the first rectangular chute plate 7010, the first return spring 7011, the first collective slat 7012, the second slider 7016, the second rectangular chute plate 7017 and the second return spring 7018, and is bilaterally symmetrical to the first engaging slat 707, the first slider 709, the first rectangular chute plate 7010, the first return spring 7011, the first collective slat 7012, the second slider 7016, the second rectangular chute plate 7017 and the second return spring 7018 with respect to the intercepting mechanism 708 as a symmetry axis, so as to ensure stable vibration of the intercepting mechanism 708.

Although the present disclosure has been described in detail with reference to the exemplary embodiments, the present disclosure is not limited thereto, and it will be apparent to those skilled in the art that various modifications and changes can be made thereto without departing from the scope of the present disclosure.

Claims

1. An ore waste treatment device comprises a bottom working frame plate (1), a first supporting high foot column (2) and a second supporting high foot column (3), and is characterized by further comprising a high-rise working frame plate (4), a side supporting window plate (5), a rolling and crushing mechanism (6), a secondary intercepting and crushing mechanism (7), a separating disc grinding mechanism (8), an operation control screen (9) and an integration strip frame (10); one side above the bottom working frame plate (1) is sequentially connected with the first supporting high-leg column (2) and the second supporting high-leg column (3), and the other side above the bottom working frame plate (1) is connected with the separating disc grinding mechanism (8); the upper part of the bottom working frame plate (1) is connected with an integrated strip frame (10); the lower part of the high-rise working frame plate (4) is sequentially connected with a first supporting high-rise column (2) and a second supporting high-rise column (3); the high-rise working frame plate (4) is connected with the operation control screen (9); the high-rise working frame plate (4) is connected with the integrating strip frame (10); one side above the high-rise working frame plate (4) is welded with the lateral supporting window plate (5), and the other side above the high-rise working frame plate (4) is connected with the separating disc grinding mechanism (8); the side supporting window plate (5) is connected with the separating disc grinding mechanism (8); the side supporting window plate (5) is connected with a secondary intercepting and crushing mechanism (7); the upper part of the secondary interception and fragmentation mechanism (7) is connected with the rolling and crushing mechanism (6); the secondary interception fragmentation mechanism (7) is connected with the integration strip frame (10);

the rolling and crushing mechanism (6) comprises a first power motor (601), a first motor plate (602), a first rotating shaft rod (603), a first driving wheel (604), a first flat gear (605), a second flat gear (606), a first rolling roller (607), a crushing cabin (608), a second rolling roller (609), a first fixed frame plate (6010) and a second fixed frame plate (6011); the lower part of the first power motor (601) is connected with a first motor plate (602) through a bolt; an output shaft of the first power motor (601) is rotationally connected with the first rotating shaft rod (603); the outer surface of the first rotating shaft rod (603) is sleeved with the first driving wheel (604); the first rotating shaft rod (603) is in rotating connection with the first flat gear (605); the first flat gear (605) is meshed with the second flat gear (606); the axle center of the first flat gear (605) is rotationally connected with the first rolling roller (607); the axle center of the second flat gear (606) is rotationally connected with the second rolling roller (609); the inner side of the crushing cabin (608) is sequentially connected with a first rolling roller (607) and a second rolling roller (609); one side of the crushing cabin (608) is connected with a first fixed frame plate (6010), and the other side of the crushing cabin (608) is connected with a second fixed frame plate (6011); the first motor plate (602) is connected with the secondary intercepting and fragmenting mechanism (7); the lower part of the first driving wheel (604) is connected with a secondary intercepting and smashing mechanism (7); the first fixed frame plate (6010) and the second fixed frame plate (6011) are connected with the secondary intercepting and fragmenting mechanism (7); the outer surface of the first rotating shaft rod (603) is connected with a secondary intercepting and crushing mechanism (7);

the secondary intercepting and smashing mechanism (7) is connected with a second driving wheel (701), a second rotating shaft rod (702), a plum blossom vibrating wheel (703), a first bearing frame plate (704), a second bearing frame plate (705), a driving arc-shaped strip (706), a first connecting strip plate (707), an intercepting mechanism (708), a first sliding block (709), a first rectangular chute plate (7010), a first rebound spring (7011), a first gathering strip plate (7012), a second gathering plate (7013), a second buffering moving mechanism (7014), a third gathering plate (7015), a second sliding block (7016), a second rectangular chute plate (7017) and a second rebound spring (7018); the inner surface of the second driving wheel (701) is sleeved with a second rotating shaft rod (702); one side of the second rotating shaft rod (702) is spliced with the second gathering plate (7013) through a bearing, and the other side of the second rotating shaft rod (702) is rotatably connected with the plum blossom vibration wheel (703); one side of the outer surface of the plum blossom vibration wheel (703) is sleeved with a second bearing frame plate (705), and the other side of the outer surface of the plum blossom vibration wheel (703) is sleeved with a first bearing frame plate (704); the plum blossom vibration wheel (703) is in transmission connection with the transmission arc-shaped strip (706); the transmission arc-shaped strip (706) is welded with the first connecting strip plate (707); the upper part of the first connecting strip plate (707) is connected with an intercepting mechanism (708); the lower part of the first linking strip plate (707) is sequentially spliced with a first sliding block (709) and a second sliding block (7016); the outer surface of the first sliding block (709) is in sliding connection with the first rectangular chute plate (7010); the outer surface of the second sliding block (7016) is in sliding connection with a second rectangular sliding groove plate (7017); one side of the first resilient spring (7011) is connected with the first sliding block (709), and the other side of the first resilient spring (7011) is connected with the first rectangular chute plate (7010); one side of the second rebound spring (7018) is connected with the second sliding block (7016), and the other side of the second rebound spring (7018) is connected with the second rectangular sliding groove plate (7017); the upper part of the first collective batten (7012) is sequentially connected with a first rectangular chute plate (7010) and a second rectangular chute plate (7017); the third collecting plate (7015) is connected with the first collecting strip plate (7012) and the second buffer moving mechanism (7014) in sequence; the upper part of the second buffer moving mechanism (7014) is connected with the interception mechanism (708); the lower part of the interception mechanism (708) is connected with a first collective slat (7012); the interception mechanism (708) is connected with the second gathering plate (7013); the upper part of the third assembly plate (7015) is connected with a second assembly plate (7013); the second gathering plate (7013) is connected with the intercepting mechanism (708); the second collecting plate (7013) is sequentially connected with the first motor plate (602) and the first rotating shaft rod (603); the second buffer moving mechanism (7014) is connected with the first fixed frame plate (6010); the first collective batten (7012) is connected with the second fixed frame plate (6011); the third gathering plate (7015) is connected with the integrated strip frame (10); the first collective slat (7012) and the second cushioning movement mechanism (7014) are both connected to the side supporting louver (5); the upper part of the second transmission wheel (701) is connected with a first transmission wheel (604); the second buffer moving mechanism (7014) is connected with the separating disc grinding mechanism (8); the third collecting plate (7015) is connected with the separating disc grinding mechanism (8);

the separating disc grinding mechanism (8) comprises a second power motor (801), a third flat gear (802), a third driving wheel (803), a fourth flat gear (804), a first grinding disc (805), a fourth driving wheel (806), a fifth flat gear (807), a second grinding disc (808), a sixth flat gear (809), a first gear rack plate (8010), a seventh flat gear (8011), a first electric sliding seat (8012), a first electric sliding rail (8013), a second electric sliding seat (8014), a second electric sliding rail (8015), a fourth gathering plate (8016), a blanking collecting cabin (8017), a fixed cabin plate (8018), a separating screen (8019), a second engaging strip plate (8020) and a waste collecting hopper (8021); an output shaft of the second power motor (801) is rotationally connected with the third horizontal gear (802); the third flat gear (802) is meshed with the fourth flat gear (804); the axle center of the third horizontal gear (802) is rotationally connected with a third driving wheel (803); the axle center of the fourth flat gear (804) is rotationally connected with the first grinding disc (805); the outer ring surface of the third driving wheel (803) 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 fifth flat gear (807); a second grinding disc (808) is arranged above the first grinding disc (805); the axle center of the second grinding disc (808) is rotationally connected with a sixth flat gear (809); the axis of the sixth flat gear (809) is inserted into the first gear frame plate (8010) through a bearing; the sixth flat gear (809) is meshed with the seventh flat gear (8011); the axis of the seventh flat gear (8011) is spliced with the first gear frame plate (8010) through a bearing; the first gear frame plate (8010) is sequentially in bolted connection with the first electric sliding seat (8012) and the second electric sliding seat (8014); the first electric sliding seat (8012) is in sliding connection with the first electric sliding rail (8013); the second electric sliding seat (8014) is in sliding connection with the second electric sliding rail (8015); a first electric sliding rail (8013) and a second electric sliding rail (8015) are sequentially connected with the upper part of the fourth gathering plate (8016); a blanking collecting cabin (8017) is arranged above the first grinding disc (805); the blanking collecting cabin (8017) is welded with the fixed cabin plate (8018); a separation screen (8019) is arranged above the blanking collection chamber (8017); one side of the separating screen (8019) is connected with a waste collecting hopper (8021); the lower part of the waste collecting hopper (8021) is welded with a second connecting lath (8020); the second linking strip (8020) is connected with the side supporting window plate (5); the separating screen (8019) is connected with the second buffer moving mechanism (7014) and the third collecting plate (7015) in sequence; the lower part of the second power motor (801) is connected with the bottom working frame plate (1); the axle center of the fourth flat gear (804) is connected with the bottom working frame plate (1); the lower part of the fourth gathering plate (8016) is connected with the bottom working frame plate (1); the axle center of the fourth transmission wheel (806) is connected with the bottom working frame plate (1); the fixed cabin plate (8018) is connected with a high-rise working frame plate (4) and a side supporting window plate (5) in sequence;

the intercepting mechanism (708) comprises a first inclined intercepting plate (70801), a first cylindrical fixed frame (70802), a second cylindrical fixed frame (70803), a second inclined intercepting plate (70804), a protective bending plate (70805), a first electric push rod (70806), a second electric push rod (70807), a triangular prism impact block (70808) and an inverted V-shaped frame (70809); one side of the first inclined interception plate (70801) is connected with a first cylindrical fixed frame (70802), and the other side of the first inclined interception plate (70801) is connected with a second cylindrical fixed frame (70803); one side of the second inclined interception plate (70804) is connected with the first cylindrical fixed frame (70802) and the other side of the second inclined interception plate (70804) is connected with the second cylindrical fixed frame (70803); a protective bending plate (70805) is arranged below the first cylindrical fixing frame (70802); the lower part of the protective bending plate (70805) is sequentially connected with a first electric push rod (70806) and a second electric push rod (70807); the upper part of the triangular prism impact block (70808) is sequentially connected with a first electric push rod (70806) and a second electric push rod (70807); the inverted V-shaped frame (70809) is connected with the protective bending plate (70805); the protective bending plate (70805) is connected with the second gathering plate (7013); the lower part of the inverted V-shaped rack (70809) is connected with a first collective slat (7012) and a second buffer moving mechanism (7014) in turn.

2. An ore waste processing apparatus according to claim 1, characterized in that the gap space formed between the first inclined interception plate (70801) and the second inclined interception plate (70804) has a minimum distance at the lowest end of the gap space of the maximum diameter allowed by crushed stones.

3. The ore waste treatment plant according to claim 2, characterized in that an electric shaft switch door is arranged at the outlet below the blanking collection chamber (8017).

4. A mineral waste processing apparatus in accordance with claim 3, characterized in that the upper surface of the first grinding disk (805) and the lower surface of the second grinding disk (808) are provided with uniform dome-shaped protrusions.

5. The ore waste processing apparatus according to claim 4, characterized in that the first grinding plate (805) is provided with a notch along the baffle plate on the side close to the blanking collection chamber (8017).

6. The ore waste treatment apparatus according to claim 5, wherein the second buffer moving mechanism (7014) has the same structure as the first engaging slat (707), the first slider (709), the first rectangular chute plate (7010), the first rebound spring (7011), the first collective slat (7012), the second slider (7016), the second rectangular chute plate (7017), and the second rebound spring (7018), and is bilaterally symmetrical to the first engaging slat (707), the first slider (709), the first rectangular chute plate (7010), the first rebound spring (7011), the first collective slat (7012), the second slider (7016), the second rectangular chute plate (7017), and the second rebound spring (7018) about the intercepting mechanism (708) as a symmetry axis.