CN114011586A - Flotation machine based on separation is carried out to ore pulp height - Google Patents
Flotation machine based on separation is carried out to ore pulp height Download PDFInfo
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- CN114011586A CN114011586A CN202111308729.1A CN202111308729A CN114011586A CN 114011586 A CN114011586 A CN 114011586A CN 202111308729 A CN202111308729 A CN 202111308729A CN 114011586 A CN114011586 A CN 114011586A
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- frame
- support frame
- sliding
- support
- ore pulp
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B03—SEPARATION OF SOLID MATERIALS USING LIQUIDS OR USING PNEUMATIC TABLES OR JIGS; MAGNETIC OR ELECTROSTATIC SEPARATION OF SOLID MATERIALS FROM SOLID MATERIALS OR FLUIDS; SEPARATION BY HIGH-VOLTAGE ELECTRIC FIELDS
- B03D—FLOTATION; DIFFERENTIAL SEDIMENTATION
- B03D1/00—Flotation
- B03D1/02—Froth-flotation processes
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B03—SEPARATION OF SOLID MATERIALS USING LIQUIDS OR USING PNEUMATIC TABLES OR JIGS; MAGNETIC OR ELECTROSTATIC SEPARATION OF SOLID MATERIALS FROM SOLID MATERIALS OR FLUIDS; SEPARATION BY HIGH-VOLTAGE ELECTRIC FIELDS
- B03D—FLOTATION; DIFFERENTIAL SEDIMENTATION
- B03D1/00—Flotation
- B03D1/14—Flotation machines
- B03D1/1443—Feed or discharge mechanisms for flotation tanks
- B03D1/1462—Discharge mechanisms for the froth
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B03—SEPARATION OF SOLID MATERIALS USING LIQUIDS OR USING PNEUMATIC TABLES OR JIGS; MAGNETIC OR ELECTROSTATIC SEPARATION OF SOLID MATERIALS FROM SOLID MATERIALS OR FLUIDS; SEPARATION BY HIGH-VOLTAGE ELECTRIC FIELDS
- B03D—FLOTATION; DIFFERENTIAL SEDIMENTATION
- B03D1/00—Flotation
- B03D1/14—Flotation machines
- B03D1/16—Flotation machines with impellers; Subaeration machines
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Abstract
The invention relates to a floating ore separator, in particular to a floating ore separator for separating based on the height of ore pulp, which comprises a first support frame, a discharge pipe, a flow stabilizing plate, a collecting frame and the like; the first support frame is fixedly provided with a support frame, the bottom of the support frame is provided with a discharge pipe, the support frame is provided with a discharge port corresponding to the discharge pipe, a pair of flow stabilizing plates are arranged in the support frame, and the two sides of the support frame are connected with a collecting frame in a fastening piece connection mode. The mineralized bubbles floating to the surface of the ore pulp are scraped out of the supporting frame through the rotation of the scraping plate, the scraped mineralized bubbles fall into the collecting frame, and the rest part of the mineralized bubbles is reserved in the ore pulp so as to achieve the purpose of separating minerals.
Description
Technical Field
The invention relates to a floating ore separator, in particular to a floating ore separator for separating based on the height of ore pulp.
Background
The flotation machine is a short name of a flotation machine and refers to mechanical equipment for completing a flotation process. The flotation machine is driven by a motor triangle belt to drive a movable impeller to rotate, a centrifugal effect is generated to form negative pressure, the ore pulp treated by adding the medicament is aerated by stirring, on one hand, sufficient air is sucked to be mixed with the ore pulp, on the other hand, the ore pulp is stirred to be mixed with the medicament, so that certain ore particles are selectively fixed on bubbles and float to the surface of the ore pulp to be scraped to form a foam product, and the rest part of the ore pulp is kept in the ore pulp to achieve the purpose of separating minerals.
The flotation machine has a plurality of structural forms, the most common flotation machine is a mechanical stirring type flotation machine, the existing mechanical stirring type flotation machine is used for inflating and stirring ore pulp, the existing mechanical stirring type flotation machine is completed by a mechanical stirring device consisting of an impeller and a customization device, the external air self-suction type flotation machine belongs to an external air self-suction type flotation machine, air is generally sucked near the mechanical stirring device at the lower part of a flotation tank, the inflation amount is small, the generated air bubbles are few, the existing mechanical stirring type flotation machine cannot control the height of the liquid level of the ore pulp, and a large amount of ore pulp can be scraped when the liquid level of the ore pulp is too high when the air bubbles are scraped.
Disclosure of Invention
The invention aims to provide a floating ore separator which can separate minerals, prevent ore pulp from overflowing and control the liquid level height of the ore pulp to separate based on the height of the ore pulp, so as to overcome the defects that the existing device has less air inflation amount, generates less bubbles, and scrapes a large amount of ore pulp when the liquid level of the ore pulp is too high.
The technical implementation scheme of the invention is as follows: a flotation machine for separation based on ore pulp height comprises a first support frame, a discharge pipe, a flow stabilizing plate, a collection frame, a feeding pipe, a second support frame, a driving bidirectional motor, a bubble generation assembly, a stirring assembly and a transmission assembly;
the first support frame is fixedly provided with a support frame, and the support frame is used for placing ore pulp;
the bottom of the support frame is provided with a discharge pipe, and the support frame is provided with a discharge hole corresponding to the discharge pipe and used for discharging ore pulp;
the flow stabilizing plates are arranged in the supporting frame and used for generating resistance to the ore pulp and playing a role in stabilizing the fluidity of the ore pulp;
the two sides of the supporting frame are connected with the collecting frame in a fastener connection mode, and the collecting frame is used for collecting mineralized bubbles;
the feeding frame is connected to one side of the supporting frame in a fastener connection mode, the feeding frame is communicated with the supporting frame, and the feeding frame is used for conveying ore pulp and medicines into the supporting frame;
the feeding pipe is arranged on the feeding frame and used for conveying ore pulp and medicines into the feeding frame;
the top of the supporting frame is fixedly provided with a second supporting frame;
the bidirectional motor is fixedly arranged on the second support frame, and an output shaft of the bidirectional motor is rotatably connected with the second support frame;
the second support frame is provided with a bubble generating assembly, and the bubble generating assembly is used for forming mineralized bubbles;
the stirring component is rotatably connected to the second supporting frame and is used for stirring the ore pulp;
the transmission assembly is arranged on the supporting frame and used for transmitting power.
Further, the bubble generating assembly comprises an air inlet pipe and a micropore stone plate, the air inlet pipe is arranged on the second support frame, the micropore stone plate is arranged on the bottom surface in the support frame, and the micropore stone plate is communicated with the air inlet pipe.
Further, mix the subassembly including first transfer line, the second transfer line, the rocking arm, the stirring fan, third transfer line and connecting rod, bearing on the second support frame is connected with first transfer line through transition fit's mode, two-way motor output shaft one end rigid coupling has the second transfer line, the second transfer line is connected with second support frame rotary type, two-way motor output shaft other end rigid coupling has the rocking arm, the same rigid coupling in first transfer line top has the rocking arm, first transfer line bottom is provided with the stirring fan, second transfer line bottom is provided with the stirring fan equally, the stirring fan contacts with micropore slabstone each other, third transfer line rotary type is connected on the second support frame, the same rigid coupling in third transfer line top has the rocking arm, common rotary type is connected with the connecting rod on the three rocking arm.
Further, the transmission component comprises a support plate, a first spring, a sliding support frame, a sliding bevel gear, a third support frame, a sliding support block, a connecting support frame, a support ring frame, a bevel gear frame and a first bevel gear, the support plate is connected with the support plate in an inner sliding manner, the support plate is rotatably connected with the first transmission rod, the support plate is also rotatably connected with the second transmission rod, the top surface of the support plate is fixedly connected with a pair of first springs, one end of each first spring is fixedly connected with the second support frame, the sliding support frame is connected with the second support frame in a sliding manner, the third transmission rod penetrates through the sliding support frame, the sliding bevel gear is rotatably connected on the sliding support frame, the third transmission rod is connected with the sliding bevel gear in a sliding manner, the top surface of the support frame is provided with four pairs of third support frames, the sliding support block is jointly connected on the two adjacent third support frames in a sliding manner, and the connecting support frame is welded on one side of the sliding support block, one end of the connecting support frame is fixedly connected with the support plate, one side of each of the two sliding support blocks is welded with a support ring frame, the two support ring frames are connected with a bevel gear frame in a rotary mode, the sliding bevel gears are matched with the bevel gear frames, and first bevel gears are arranged at two ends of each support ring frame.
Further, still including the separable set spare, the last rotation type of sliding support piece is connected with the separable set spare, and the separable set spare is including rotating mounting bracket, second bevel gear and striking off the board, and common rotation type is connected with the rotation mounting bracket on two sliding support pieces of homonymy, and the welding of rotation mounting bracket one end has second bevel gear, and second bevel gear and first bevel gear intermeshing rotate and are provided with the mode that is circumference and distribute on the mounting bracket and strike off the board.
Further, still including the buoyancy board, the backup pad bottom surface is provided with the buoyancy board, and the buoyancy board is connected with carriage slidingtype, and the buoyancy board is connected with first transfer line rotary type, and the buoyancy board is connected with second transfer line rotary type equally.
The novel floating plate comprises a supporting frame, and is characterized by further comprising a baffle adjusting assembly, wherein the supporting frame is symmetrically and slidably connected with the baffle adjusting assembly, the baffle adjusting assembly comprises a baffle body and a connecting frame, the supporting frame is symmetrically and slidably connected with the baffle body, one side of the baffle body is welded with a pair of connecting frames, and one end of each connecting frame is connected with the bottom surface of the floating plate.
Further, still including antiseized even subassembly, the slip supporting shoe top is provided with antiseized even subassembly, and antiseized even subassembly is including fourth support frame, slip scraper blade and second spring, and the welding of slip supporting shoe top has the fourth support frame, and common sliding connection has the slip scraper blade on two fourth support frames of homonymy, and the hookup has a pair of second spring on the slip scraper blade, second spring one end and fourth support frame rigid coupling.
Further, still including the feeding control subassembly, the sliding type is connected with the feeding control subassembly on the carriage, and the feeding control subassembly is including sliding plate and stirring frame, and the sliding type is connected with the sliding plate on the carriage, and sliding plate one side rigid coupling has a pair of stirring frame, stirs the frame and runs through the buoyancy board, stirs the frame and runs through the backup pad equally.
The invention has the following advantages:
the ore pulp is stirred by the rotation of the two stirring fans, so that the ore pulp and the medicine are fully mixed, and meanwhile, the effect of refining bubbles is achieved, certain mineral particles in the ore pulp are selectively bonded on the bubbles and float to the surface of the ore pulp to form mineralized bubbles.
The mineralized bubbles floating to the surface of the ore pulp are scraped out of the supporting frame through the rotation of the scraping plate, the scraped mineralized bubbles fall into the collecting frame, and the rest part of the mineralized bubbles is reserved in the ore pulp so as to achieve the purpose of separating minerals.
The buoyancy plate is influenced by the rising of the liquid level of the ore pulp, so that the connecting frame drives the baffle body to move upwards, the two sides above the supporting frame are blocked by the baffle body, and the ore pulp is prevented from overflowing from the supporting frame.
Through the effect of buoyancy board for the sliding plate can be according to liquid level upwards or downstream, thereby the size that the control sliding plate was opened the feeding frame feed inlet, and then the volume of control conveying ore pulp towards in the carriage, reaches the ore pulp liquid level's in the control carriage purpose with this.
Drawings
Fig. 1 is a schematic perspective view of a first embodiment of the present invention.
Fig. 2 is a schematic perspective view of a second embodiment of the present invention.
Fig. 3 is a partial perspective view of the present invention.
Fig. 4 is a schematic sectional perspective view of a bubble generation assembly and an agitation assembly according to the present invention.
Fig. 5 is a schematic perspective view of a portion of a whipping assembly of the present invention.
Fig. 6 is a partially disassembled perspective view of an agitated assembly according to the invention.
Fig. 7 is a partially cut-away perspective view of the transmission assembly of the present invention.
Fig. 8 is a schematic view of a first partially assembled body of the transmission assembly of the present invention.
Fig. 9 is a schematic view of a second partial body structure of the transmission assembly of the present invention.
Fig. 10 is a perspective view of the separator assembly of the present invention.
Fig. 11 is a schematic perspective view of a first baffle adjustment assembly of the present invention.
Fig. 12 is a schematic perspective view of a second embodiment of the damper adjustment assembly of the present invention.
Fig. 13 is a schematic perspective view of an anti-adhesion assembly of the present invention.
FIG. 14 is a schematic cross-sectional perspective view of a feed control assembly of the present invention.
FIG. 15 is a schematic perspective view of a feed control assembly according to the present invention.
The meaning of the reference symbols in the figures: 1: first support frame, 21: support frame, 2101: discharge pipe, 212: flow stabilizer, 22: collection frame, 23: feed block, 231: feed tube, 31: second support, 32: bidirectional motor, 4: bubble generation assembly, 41: intake pipe, 42: microporous slate, 5: agitating assembly, 51: first drive lever, 511: second transmission lever, 512: rocker arm, 52: stirring fan, 53: third driving lever, 54: connecting rod, 6: transmission assembly, 61: support plate, 62: first spring, 63: sliding support frame, 64: sliding helical gear, 65: third support, 66: sliding support block, 661: connecting support frame, 67: support ring frame, 68: oblique carrier, 69: first bevel gear, 7: separation assembly, 71: rotating the mounting frame, 72: second bevel gear, 73: scraping plate, 8: buoyancy plate, 9: baffle adjustment assembly, 91: baffle body, 92: connecting frame, 10: adhesion-preventing assembly, 101: fourth support bracket, 102: sliding blade, 103: second spring, 11: feed control assembly, 111: sliding plate, 112: a poking frame.
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.
Example 1
A flotation ore separator based on ore pulp height comprises a first support frame 1, a support frame 21, a discharge pipe 2101, a flow stabilizing plate 212, a collection frame 22, a feeding frame 23, a feeding pipe 231, a second support frame 31, a two-way motor 32, a bubble generation assembly 4, a stirring assembly 5 and a transmission assembly 6, wherein the support frame 21 is fixedly installed on the first support frame 1, the bottom of the support frame 21 is provided with the discharge pipe 2101, the support frame 21 is provided with a discharge hole corresponding to the discharge pipe 2101, the support frame 21 is internally provided with a pair of flow stabilizing plates 212, two sides of the support frame 21 are connected with the collection frame 22 through fasteners, one side of the support frame 21 is connected with the feeding frame 23 through fasteners, the feeding pipe 231 is used for conveying ore pulp and medicines into the feeding frame 23, the feeding frame 23 is communicated with the support frame 21, the feeding pipe 231 for conveying ore pulp and medicines is arranged on the feeding frame 23, the top fixed mounting of carriage 21 has second support frame 31, and fixed mounting has two-way motor 32 on the second support frame 31, and two-way motor 32 output shaft is connected with second support frame 31 rotary type, is provided with bubble production subassembly 4 on the second support frame 31, and the last rotation type of second support frame 31 is connected with stirring subassembly 5, is provided with drive assembly 6 on the carriage 21.
The air bubble generating assembly 4 comprises an air inlet pipe 41 and a micropore stone plate 42, the air inlet pipe 41 used for conveying air is arranged on the second support frame 31, the micropore stone plate 42 is arranged on the inner bottom surface of the support frame 21, the micropore stone plate 42 is used for discharging air and mixing the air and the ore pulp to form air bubbles, and the micropore stone plate 42 is communicated with the air inlet pipe 41.
The stirring component 5 comprises a first transmission rod 51, a second transmission rod 511, a rocker arm 512, a stirring fan 52, a third transmission rod 53 and a connecting rod 54, wherein the first transmission rod 51 is connected to a bearing on the second support frame 31 close to the air inlet pipe 41 in a transition fit manner, the second transmission rod 511 is fixedly connected to one end of an output shaft of the two-way motor 32, the second transmission rod 511 is rotatably connected with the second support frame 31, the rocker arm 512 is fixedly connected to the other end of the output shaft of the two-way motor 32, the rocker arm 512 is fixedly connected to the top end of the first transmission rod 51 far away from the two-way motor 32, the stirring fan 52 is arranged at the bottom end of the first transmission rod 51 and is used for stirring ore pulp, the stirring fan 52 is also arranged at the bottom end of the second transmission rod 511, the stirring fan 52 is in contact with the microporous stone plate 42, the third transmission rod 53 is rotatably connected to the second support frame 31 close to the two-way motor 32, the top end of the third transmission rod 53 far away from the stirring fan 52 is also fixedly connected with the rocker arm 512, the three rocker arms 512 are connected with the connecting rod 54 in a rotating mode.
The transmission assembly 6 comprises a support plate 61, a first spring 62, a sliding support frame 63, a sliding bevel gear 64, a third support frame 65, a sliding support block 66, a connecting support frame 661, a support ring frame 67, a bevel gear frame 68 and a first bevel gear 69, the support plate 61 is connected with the support frame 21 in a sliding manner, the support plate 61 is connected with the first transmission rod 51 in a rotating manner, the support plate 61 is also connected with the second transmission rod 511 in a rotating manner, the top surface of the support plate 61 is fixedly connected with a pair of first springs 62, one end of the first spring 62 far away from the support plate 61 is fixedly connected with the second support frame 31, the sliding support frame 63 is connected with the second support frame 31 in a sliding manner, the third transmission rod 53 passes through the sliding support frame 63, the sliding support frame 63 is connected with the sliding bevel gear 64 in a rotating manner, the third transmission rod 53 is connected with the sliding bevel gear 64 in a sliding manner, the top surface of the support frame 21 is provided with four pairs of third support frames 65, the adjacent two third support frames 65 are jointly connected with sliding support blocks 66 in a sliding manner, one side of each sliding support block 66 is welded with a connecting support frame 661, one end of each connecting support frame 661 is fixedly connected with the support plate 61, one side of each sliding support block 66, which is close to the connecting support frame 661, is welded with a support ring frame 67, the two support ring frames 67 are jointly and rotatably connected with bevel gear frames 68, the sliding bevel gears 64 are mutually matched with the bevel gear frames 68, and the two ends of each support ring frame 67 are provided with first bevel gears 69.
When the device is used, the feeding pipe 231 is connected with the conveying pipeline, the external air conveying pipe is connected with the air inlet pipe 41, the conveying pipeline conveys ore pulp and medicines into the feeding frame 23 through the feeding pipe 231, the ore pulp and the medicines can slide into the supporting frame 21 from the feeding frame 23, the external air conveying pipe conveys air into the micropore stone plate 42 through the air inlet pipe 41, and the micropore stone plate 42 discharges the air and mixes the air with the ore pulp to form bubbles.
The worker manually starts the two-way motor 32, the output shaft of the two-way motor 32 rotates to drive the second transmission rod 511 and the stirring fan 52 to rotate, meanwhile, the output shaft of the two-way motor 32 rotates to drive one rocker arm 512 to rotate, the rocker arm 512 drives the other two rocker arms 512 and the upper device thereof to rotate through the connecting rod 54, the two stirring fans 52 rotate to stir the ore pulp, so that the ore pulp and the medicine are fully mixed, and meanwhile, the bubbles are refined, so that certain mineral particles in the ore pulp are selectively bonded on the bubbles and float to the surface of the ore pulp to form mineralized bubbles.
Example 2
On the basis of embodiment 1, as shown in fig. 10 and 13, the separation device further includes a separation assembly 7, the sliding support blocks 66 are rotatably connected with the separation assembly 7, the separation assembly 7 is used for separating minerals from ore pulp, the separation assembly 7 includes a rotating mounting frame 71, a second bevel gear 72 and a scraping plate 73, the two sliding support blocks 66 on the same side are rotatably connected with the rotating mounting frame 71, the second bevel gear 72 is welded at one end of the rotating mounting frame 71, the second bevel gear 72 is meshed with the first bevel gear 69, the scraping plates 73 are arranged on the rotating mounting frame 71 in a circumferentially distributed manner, and the scraping plate 73 is used for scraping mineralized bubbles floating on the surface of the ore pulp from the support frame 21.
The third transmission rod 53 rotates to drive the sliding bevel gear 64 to rotate, the sliding bevel gear 64 drives the bevel gear rack 68 and the first bevel gear 69 to rotate, the first bevel gear 69 drives the second bevel gear 72 and the device thereon to rotate, the scraping plate 73 rotates to scrape out the mineralized bubbles floating on the surface of the ore pulp from the supporting frame 21, the scraped mineralized bubbles fall into the collecting frame 22, and the rest part of the mineralized bubbles is retained in the ore pulp to achieve the purpose of separating minerals.
Example 3
On the basis of embodiment 2, as shown in fig. 11 to 12, the device further includes a buoyancy plate 8, the buoyancy plate 8 is disposed on the bottom surface of the supporting plate 61, the buoyancy plate 8 is slidably connected to the supporting frame 21, the buoyancy plate 8 is rotatably connected to the first transmission rod 51, the buoyancy plate 8 is also rotatably connected to the second transmission rod 511, and the buoyancy plate 8 is used for driving the supporting plate 61 to move upward.
Still including baffle adjusting part 9, the symmetry sliding type is connected with baffle adjusting part 9 on the carriage 21, and baffle adjusting part 9 is used for blocking the ore pulp, and baffle adjusting part 9 is including baffle body 91 and link 92, and the symmetry sliding type is connected with baffle body 91 on the carriage 21, and baffle body 91 is used for blocking carriage 21 top both sides, and the welding of baffle body 91 one side has a pair of link 92, and link 92 one end couples with 8 bottoms of buoyancy board.
When the ore pulp liquid level in the carriage 21 risees, the ore pulp can promote buoyancy board 8 and the upward movement of last device, and buoyancy board 8 drives baffle body 91 upward movement through link 92 for baffle body 91 blocks carriage 21 top both sides, prevents that the ore pulp from overflowing.
Example 4
On the basis of embodiment 3, as shown in fig. 13, the multifunctional scraping device further includes an anti-adhesion assembly 10, the anti-adhesion assembly 10 is disposed at the top of the sliding support block 66, the anti-adhesion assembly 10 prevents mineralized bubbles from adhering to the scraping plate 73, the anti-adhesion assembly 10 includes a fourth support frame 101, a sliding scraper 102 and a second spring 103, the fourth support frame 101 is welded at the top of the sliding support block 66, the sliding scraper 102 is jointly slidably connected to the two fourth support frames 101 on the same side, the sliding scraper 102 is used for scraping the mineralized bubbles adhering to the scraping plate 73, the sliding scraper 102 is connected to a pair of second springs 103, and one end of each second spring 103 is fixedly connected to the fourth support frame 101.
When the scraping plate 73 rotates to scrape out the mineralized bubbles floating on the surface of the ore pulp from the supporting frame 21, the scraping plate 73 pushes the sliding scraper 102 to move upwards, and the sliding scraper 102 can scrape the mineralized bubbles adhered to the scraping plate 73, so that the mineralized bubbles adhered too much to the scraping plate 73 are prevented from being brought back to the ore pulp. When the scraping plate 73 is separated from the sliding blade 102, the compressed second spring 103 is restored to drive the sliding blade 102 to move downward and restore.
Example 5
On the basis of embodiment 4, as shown in fig. 14 to 15, the slurry feeder further includes a feeding control assembly 11, the supporting frame 21 is slidably connected with the feeding control assembly 11, the feeding control assembly 11 is configured to control a liquid level of slurry in the supporting frame 21, the feeding control assembly 11 includes a sliding plate 111 and a toggling frame 112, the supporting frame 21 is slidably connected with the sliding plate 111, the sliding plate 111 is configured to block a portion of a feeding port of the feeding frame 23, one side of the sliding plate 111 is fixedly connected with a pair of toggling frames 112, the toggling frame 112 penetrates through the floating plate 8, and the toggling frame 112 also penetrates through the supporting plate 61.
When the liquid level of the ore pulp in the supporting frame 21 is higher, the buoyancy plate 8 and the upper device thereof move upwards, the supporting plate 61 drives the toggle frame 112 and the sliding plate 111 to move upwards, and the sliding plate 111 blocks a part of the feeding hole of the feeding frame 23, so that the amount of the ore pulp conveyed into the supporting frame 21 by the feeding frame 23 is reduced. When the liquid level of the ore pulp in the supporting frame 21 drops, the compressed first spring 62 is reset to drive the supporting plate 61 and the upper device thereof to move downwards, the supporting plate 61 drives the poking frame 112 and the sliding plate 111 to move downwards, the sliding plate 111 does not block the feed port of the feeding frame 23 any more, so that the amount of the ore pulp conveyed into the supporting frame 21 is increased, and the purpose of controlling the liquid level of the ore pulp in the supporting frame 21 is achieved. After the operation is finished, the conveying pipeline does not convey the ore pulp and the medicine into the feeding frame 23 any more, the external air conveying pipe stops conveying air to the air inlet pipe 41, the worker manually closes the two-way motor 32 to stop the operation of the equipment, and the worker manually opens the valve on the discharging pipe 2101 to discharge the rest ore pulp from the discharging pipe 2101.
Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.
Claims (9)
1. The utility model provides a flotation separation machine based on ore pulp height separates which characterized by: comprises a first supporting frame, a discharging pipe, a flow stabilizing plate, a collecting frame, a feeding pipe, a second supporting frame, a bidirectional motor for driving, a bubble generating assembly, a stirring assembly and a transmission assembly;
the first support frame is fixedly provided with a support frame, and the support frame is used for placing ore pulp;
the bottom of the support frame is provided with a discharge pipe, and the support frame is provided with a discharge hole corresponding to the discharge pipe and used for discharging ore pulp;
the flow stabilizing plates are arranged in the supporting frame and used for generating resistance to the ore pulp and playing a role in stabilizing the fluidity of the ore pulp;
the two sides of the supporting frame are connected with the collecting frame in a fastener connection mode, and the collecting frame is used for collecting mineralized bubbles;
the feeding frame is connected to one side of the supporting frame in a fastener connection mode, the feeding frame is communicated with the supporting frame, and the feeding frame is used for conveying ore pulp and medicines into the supporting frame;
the feeding pipe is arranged on the feeding frame and used for conveying ore pulp and medicines into the feeding frame;
the top of the supporting frame is fixedly provided with a second supporting frame;
the bidirectional motor is fixedly arranged on the second support frame, and an output shaft of the bidirectional motor is rotatably connected with the second support frame;
the second support frame is provided with a bubble generating assembly, and the bubble generating assembly is used for forming mineralized bubbles;
the stirring component is rotatably connected to the second supporting frame and is used for stirring the ore pulp;
the transmission assembly is arranged on the supporting frame and used for transmitting power.
2. The flotation machine for separation based on pulp height according to claim 1, which is characterized in that: the bubble generating assembly comprises an air inlet pipe and a micropore stone plate, the air inlet pipe is arranged on the second support frame, the micropore stone plate is arranged on the bottom surface in the support frame, and the micropore stone plate is communicated with the air inlet pipe.
3. The flotation machine for separation based on pulp height according to claim 2, characterized in that: mix the subassembly including first transfer line, the second transfer line, the rocking arm, stir the fan, third transfer line and connecting rod, bearing on the second support frame is connected with first transfer line through transition fit's mode, two-way motor output shaft one end rigid coupling has the second transfer line, the second transfer line is connected with second support frame rotary type, two-way motor output shaft other end rigid coupling has the rocking arm, the same rigid coupling in first transfer line top has the rocking arm, first transfer line bottom is provided with the stirring fan, second transfer line bottom is provided with the stirring fan equally, the stirring fan contacts with micropore slabstone each other, third transfer line rotary type is connected on the second support frame, the same rigid coupling in third transfer line top has the rocking arm, common rotary type is connected with the connecting rod on the three rocking arm.
4. The flotation machine for separation based on pulp height according to claim 3, characterized in that: the transmission component comprises a support plate, a first spring, a sliding support frame, a sliding bevel gear, a third support frame, a sliding support block, a connecting support frame, a support ring frame, a bevel gear frame and a first bevel gear, wherein the sliding support plate is connected in the support frame and rotatably connected with the first transmission rod, the support plate is also rotatably connected with the second transmission rod, the top surface of the support plate is fixedly connected with a pair of first springs, one end of each first spring is fixedly connected with the second support frame, the sliding support frame is slidably connected on the second support frame, the third transmission rod penetrates through the sliding support frame, the sliding bevel gear is rotatably connected on the sliding support frame, the third transmission rod is slidably connected with the sliding bevel gear, the top surface of the support frame is provided with four pairs of third support frames, the sliding support block is commonly slidably connected on two adjacent third support frames, and the connecting support frame is welded on one side of the sliding support block, one end of the connecting support frame is fixedly connected with the support plate, one side of each of the two sliding support blocks is welded with a support ring frame, the two support ring frames are connected with a bevel gear frame in a rotary mode, the sliding bevel gears are matched with the bevel gear frames, and first bevel gears are arranged at two ends of each support ring frame.
5. The flotation machine for separation based on pulp height according to claim 4, which is characterized in that: still including the separable set spare, the last rotation type of sliding support piece is connected with the separable set spare, and the separable set spare is connected with the separable set spare including rotating the mounting bracket, second bevel gear and striking off the board, and common rotary type is connected with the rotation mounting bracket on two sliding support pieces of homonymy, rotates the welding of mounting bracket one end, and second bevel gear and first bevel gear intermeshing rotate and are the mode that circumference distributes on the mounting bracket and be provided with and strike off the board.
6. The flotation machine for separation based on pulp height according to claim 5, which is characterized in that: still including the buoyancy board, the backup pad bottom surface is provided with the buoyancy board, and the buoyancy board is connected with the carriage slidingtype, and the buoyancy board is connected with first transfer line rotary type, and the buoyancy board is connected with second transfer line rotary type equally.
7. The flotation machine for separation based on pulp height according to claim 6, which is characterized in that: the buoyancy plate adjusting device is characterized by further comprising a baffle adjusting assembly, the supporting frame is symmetrically and slidably connected with the baffle adjusting assembly, the baffle adjusting assembly comprises a baffle body and a connecting frame, the supporting frame is symmetrically and slidably connected with the baffle body, one side of the baffle body is welded with a pair of connecting frames, and one end of each connecting frame is connected with the bottom surface of the buoyancy plate.
8. The flotation machine for separation based on pulp height according to claim 7, characterized in that: the anti-sticking assembly is arranged at the top of the sliding support block and comprises a fourth support frame, a sliding scraper and a second spring, the fourth support frame is welded at the top of the sliding support block, the sliding scraper is connected to the two fourth support frames at the same side in a common sliding mode, the sliding scraper is connected to a pair of second springs, and one end of each second spring is fixedly connected with the corresponding fourth support frame.
9. The flotation machine for separation based on pulp height according to claim 8, characterized in that: still including feeding control assembly, the sliding type is connected with feeding control assembly on the carriage, and feeding control assembly is including the sliding plate and stirs the frame, and the sliding type is connected with the sliding plate on the carriage, and sliding plate one side rigid coupling has a pair of frame of stirring, stirs the frame and runs through the buoyancy board, stirs the frame and runs through the backup pad equally.
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