CN217830735U - Sieving mechanism of ferro-aluminum alloy processing usefulness - Google Patents

Abstract

The utility model belongs to the ferroaluminum screening field, specific sieving mechanism that ferroaluminum processing was used that says so, including the sieve feed bin, sieve feed bin discharge gate sets up in the conveyer belt top, and the rigid coupling has the conveying support on the conveying base, conveying motor is installed to conveying support top lateral wall, the conveying motor output is connected with first pivot, and strong magnetic conveyor installs in first pivot and second pivot, is provided with aluminium recovery storehouse under the strong magnetic conveyor discharge end, the inside first colloid storehouse that is provided with in aluminium recovery storehouse, the inside one deck filter screen that is provided with in aluminium recovery storehouse, the water pump is installed to aluminium recovery storehouse outer wall, the rigid coupling has the raceway on the water pump, the raceway below is provided with second colloid storehouse, makes ferroaluminum realized twice screening, has solved the not thorough problem of ferroaluminum screening, and saves the manpower and materials that the screening in-process produced.

Description

Sieving mechanism of ferro-aluminum alloy processing usefulness

Technical Field

The utility model relates to the ferro-aluminum screening field specifically is a sieving mechanism of ferro-aluminum alloy processing usefulness.

Background

The simple substance of the aluminum is a silver white light metal, has ductility, and is widely applied to three important industries of aviation, construction and automobile, the pure iron is a flexible silver white metal with better ductility and is used for manufacturing iron cores of generators and motors, and the iron and the compound thereof are also used for manufacturing magnets, medicines, ink, pigment, grinding materials and the like, and are one of the black metals in the industry, so the screening of the aluminum iron metal is more and more important;

the aluminum-iron alloy screening device on the current market is mainly composed of a single filter screen and a base;

therefore, the existing aluminum-iron alloy screening device cannot control the size of screened particles, and can only carry out screening once, and the screening of aluminum and iron is not thorough, and then the screening device for processing the aluminum-iron alloy is provided.

SUMMERY OF THE UTILITY MODEL

In order to compensate the not enough of prior art, solve the problem that exists among the prior art, the utility model provides a sieving mechanism of ferro-aluminum alloy processing usefulness.

The utility model provides a technical scheme that its technical problem adopted is: the utility model relates to a screening device for processing aluminum-iron alloy, which comprises a screening base; sieve material base rigid coupling has the sieve material pivot, sieve material pivot is rotated with the supporting shoe and is connected, the supporting shoe rigid coupling is in the one end bottom of sieve feed bin, sieve feed bin other end bottom rigid coupling has spring assembly, the spring assembly lower part is connected with the vibrating motor output, the vibrating motor rigid coupling is on vibration base, sieve feed bin inner wall rigid coupling has the striker plate, the lower part is provided with the screen cloth in the sieve feed bin, and the storehouse setting is retrieved to the particle under the particle export, sieve feed bin one end is opened there is the discharge gate.

Preferably, the discharge gate sets up directly over strong magnetic conveyor belt material loading end, is convenient for carry out the follow-up processing on sending bulky iron and aluminium to strong magnetic conveyor belt after screening the particle size.

Preferably, rigid coupling conveying support on the conveying base, conveying support both ends inboard is rotated and is installed first pivot and second pivot, conveying motor is installed in the conveying support one end outside, conveying motor's output and first pivot are connected, and strong magnetic conveyor belt movable mounting is in first pivot and second pivot, strong magnetic conveyor belt below is provided with iron recovery bin, the inside scraper blade that is provided with in iron recovery bin is convenient for will make strong magnetic conveyor belt adsorb the iron grain to tentatively carry out iron-aluminum screening.

Preferably, the strong magnetic conveyer belt is hugged closely to the scraper blade upper end, is convenient for make on the strong magnetic conveyer belt adsorb the iron grain and go out through the scraper blade, does not influence subsequent continuous magnet.

Preferably, a first colloid bin is arranged right below the discharge end of the strong magnetic conveyor belt, so that the remaining aluminum and the unremoved iron can enter the first colloid bin for secondary screening.

Preferably, first colloid storehouse is placed in the inside of aluminium recovery storehouse, the well lower part in the aluminium recovery storehouse is provided with the one deck filter screen, the aluminium recovery storehouse lateral wall of filter screen lower extreme opens there is the apopore, the water pump is installed to the aluminium recovery storehouse outer wall, water pump one side and water piping connection, the raceway below is provided with second colloid storehouse, is convenient for filter aluminium on the filter screen, recycles the colloid simultaneously, accomplishes lasting secondary screening.

The utility model discloses an useful part lies in:

1. the utility model discloses a pour into mixed metal of aluminium and iron in the sieve feed bin, open vibrating motor simultaneously, vibrating motor makes the sieve feed bin vibration through spring assembly, small granule falls into the screen cloth and falls into the particle recovery storehouse from below particle export, the large granule falls into strong magnetic conveyor through the discharge gate, conveying motor drives strong magnetic conveyor and rotates, adsorb iron particle on the surface, the scraper blade of below scrapes iron particle from strong magnetic conveyor and falls into iron recovery storehouse, thereby the size of uncontrollable screening granule and the problem of iron first screening have been solved.

2. The utility model discloses a will fall into first colloid storehouse with remaining aluminium grain and the iron grain that does not remove cleanly in, the density of colloid is greater than aluminium and is less than iron, the aluminium grain floats on the upper strata, the iron grain that does not remove cleanly sinks in the bottom, the colloid spills over to aluminium when heavy iron is too much in retrieving the storehouse, aluminium was filtered out by the filter screen this moment, the colloid that spills over flows through the filter screen and gets into the apopore, make the colloid flow into second colloid storehouse through the water pump, when iron sinks to fill up first colloid storehouse, the colloid of overflow also fills in second colloid storehouse, then pour the iron grain of screening once more from first colloid storehouse, take out the aluminium grain on the filter screen, put into second colloid storehouse simultaneously, continue to screen.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without inventive exercise.

Fig. 1 is a perspective view of a first perspective according to a first embodiment;

FIG. 2 is a schematic perspective cross-sectional view of the first embodiment;

FIG. 3 is a structural diagram illustrating a second view angle according to the first embodiment;

FIG. 4 is an enlarged schematic view of the structure at A in FIG. 1;

FIG. 5 is an enlarged view of the structure at B of FIG. 1;

FIG. 6 is an enlarged view of the structure at C in FIG. 2;

FIG. 7 is an enlarged view of the structure of FIG. 3 at D;

fig. 8 is an enlarged schematic view of the structure at E in fig. 3.

In the figure: 1. a material screening base; 101. a material screening rotating shaft; 102. a support block; 103. screening a stock bin; 104. a striker plate; 105. a vibrating base; 106. a vibration motor; 107. a spring assembly; 108. a particulate outlet; 109. a particle recovery bin; 110. screening a screen; 111. a discharge port; 2. a transport base; 201. a delivery carriage; 202. a transfer motor; 203. a strong magnetic conveyor belt; 204. a first rotating shaft; 205. a second rotating shaft; 206. a squeegee; 207. an iron recovery bin; 3. an aluminum recovery bin; 301. a first colloid bin; 302. a second colloid bin; 303. a water pump; 304. a water delivery pipe; 305. a filter screen; 306. and (4) water outlet holes.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

Example one

Referring to fig. 1-8, a screening device for processing al-fe alloy includes a screening base 1; the screening base 1 is fixedly connected with a screening rotating shaft 101, the screening rotating shaft 101 is rotatably connected with a supporting block 102, the supporting block 102 is fixedly connected to the bottom of one end of a screening bin 103, the bottom of the other end of the screening bin 103 is fixedly connected with a spring assembly 107, the lower portion of the spring assembly 107 is connected with the output end of a vibration motor 106, the vibration motor 106 is fixedly connected to a vibration base 105, a material baffle plate 104 is fixedly connected to the inner wall of the screening bin 103, a screen 110 is arranged at the middle lower portion in the screening bin 103, a particle recovery bin 109 is arranged under a particle outlet 108, and a discharge port 111 is formed at one end of the screening bin 103;

during operation, realized making sieve feed bin 103 detach the ferroaluminum of small volume and retrieve through particle recovery storehouse 109 through vibrating motor 106, screened the ferroaluminum of bulky simultaneously, carried out subsequent separation processing to the great ferroaluminum of volume.

The discharge hole 111 is arranged right above the feeding end of the strong magnetic conveyor belt 203;

during operation, the screened large-volume aluminum iron is conveyed to the strong magnetic conveyor belt 203, and preliminary iron removal is carried out on the large-volume aluminum iron in the next step.

A conveying support 201 is fixedly connected to the conveying base 2, a first rotating shaft 204 and a second rotating shaft 205 are rotatably mounted on the inner sides of two ends of the conveying support 201, a conveying motor 202 is mounted on the outer side of one end of the conveying support 201, the output end of the conveying motor 202 is connected with the first rotating shaft 204, a strong magnetic conveying belt 203 is movably mounted on the first rotating shaft 204 and the second rotating shaft 205, an iron recovery bin 207 is arranged below the strong magnetic conveying belt 203, and a scraper 206 is arranged inside the iron recovery bin 207;

the during operation drives strong magnetic conveyor belt 203 through starting conveying motor 202 and rotates, and the absorption to iron at strong magnetic conveyor belt 203 pivoted in-process makes the iron grain adsorb on it, and the aluminium grain does not adsorb, has realized the first screening of aluminium iron, screens out the district with most iron in the aluminium-iron alloy.

The upper end of the scraper 206 is tightly attached to the strong magnetic conveyor belt 203.

During operation, the scraper 206 scrapes off the iron particles adsorbed on the ferromagnetic conveyor belt 203, so that the collection of iron and the removal of the surface of the ferromagnetic conveyor belt 203 by the iron recovery bin 207 are realized, and the subsequent adsorption is continuously performed.

A first colloid bin 301 is arranged right below the discharge end of the strong magnetic conveyor belt 203;

when in work, the aluminum iron after the primary iron removal enters the first colloid bin 301 to be subjected to subsequent screening treatment,

the first colloid bin 301 is placed inside the aluminum recovery bin 3, a filter screen 305 is arranged at the middle lower part in the aluminum recovery bin 3, a water outlet hole 306 is formed in the side wall of the aluminum recovery bin 3 at the lower end of the filter screen 305, a water pump 303 is installed on the outer wall of the aluminum recovery bin 3, one side of the water pump 303 is connected with a water conveying pipe 304, and a second colloid bin 302 is arranged below the water conveying pipe 304;

the during operation, when iron sinks to fill up first colloid storehouse 301, the colloid that spills over flows through filter screen 305 and gets into apopore 306, makes the colloid flow into second colloid storehouse 302 through water pump 303, pours the iron grain of secondary screening out from first colloid storehouse 301, takes out the aluminium grain from filter screen 305, puts into second colloid storehouse 302 simultaneously, continues to filter, has realized the secondary screening to the aluminium iron to and the recycling of colloid.

Example two

Referring to fig. 2, in a first comparative example, as another embodiment of the present invention, a striker plate 104 is fixedly connected to an inner wall of the screening bin 103; during operation, pour into a large amount of aluminium irons messenger in to sieve feed bin 103, can not make partial aluminium iron directly enter into sieve feed bin 103, under the effect through striker plate 104, realize blockking of aluminium iron, guaranteed that the meticulous degree to aluminium iron volume screening is higher.

The working principle is that mixed metal of aluminum and iron is poured into the screening bin 103, the vibration motor 106 is started at the same time, the vibration motor 106 enables the screening bin 103 to vibrate through the spring assembly 107, tiny particles fall into the screen 110 and fall into the particle recovery bin 109 from the particle outlet 108 below, large particles fall into the strong magnetic conveyor belt 203 through the discharge port 111, the conveyor motor 202 drives the strong magnetic conveyor belt 203 to rotate, the iron particles are attached to the surface, the iron particles are scraped off from the strong magnetic conveyor belt 203 by the scraper 206 below and fall into the iron recovery bin 207, the rest aluminum particles and the iron particles which are not removed fall into the first colloid bin 301, the density of colloid is higher than that of aluminum and lower than that of iron, the aluminum particles float on the upper layer, the iron particles which are not removed sink to the bottom, when the sinking iron is too much, the colloid overflows into the aluminum recovery bin 3, the aluminum is filtered by the filter screen 305, the overflowed colloid flows through the filter screen 305 and enters the water outlet hole 306, the colloid flows into the second colloid bin 302 through the water pump 303, when the first iron particle sinks, the colloid overflows into the second colloid bin 302, the colloid is filtered by the colloid bin 302, and the colloid is filtered by the second colloid bin 302, and the colloid is filtered by the colloid bin 302, and the colloid is filtered by the colloid bin 301.

In the description herein, references to the description of "one embodiment," "an example," "a specific example," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The foregoing shows and describes the basic principles, essential features, and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the above embodiments, and that the foregoing embodiments and descriptions are provided only to illustrate the principles of the present invention without departing from the spirit and scope of the present invention.

Claims (6)

1. The utility model provides a sieving mechanism of ferro-aluminum alloy processing usefulness which characterized in that: comprises a screening base (1); sieve material base (1) rigid coupling has sieve material pivot (101), sieve material pivot (101) rotate with supporting shoe (102) to be connected, supporting shoe (102) rigid coupling is in the one end bottom of sieve feed bin (103), sieve feed bin (103) other end bottom rigid coupling has spring assembly (107), spring assembly (107) lower part is connected with vibrating motor (106) output, vibrating motor (106) rigid coupling is on vibrating base (105), sieve feed bin (103) inner wall rigid coupling has striker plate (104), sieve feed bin (103) interior well lower part is provided with screen cloth (110), and particle recovery storehouse (109) set up under particle export (108), sieve feed bin (103) one end is opened there is discharge gate (111).

2. The screening apparatus for aluminum-iron alloy processing according to claim 1, wherein: the discharge hole (111) is arranged right above the feeding end of the strong magnetic conveyor belt (203).

3. The screening device for processing the aluminum-iron alloy according to claim 2, wherein the screening device comprises: rigid coupling conveying support (201) on conveying base (2), conveying support (201) both ends inboard is rotated and is installed first pivot (204) and second pivot (205), conveying motor (202) are installed in conveying support (201) one end outside, the output and first pivot (204) of conveying motor (202) are connected, and strong magnetic conveyor belt (203) movable mounting is on first pivot (204) and second pivot (205), strong magnetic conveyor belt (203) below is provided with iron recovery bin (207), iron recovery bin (207) inside is provided with scraper blade (206).

4. The screening apparatus for aluminum-iron alloy processing according to claim 3, wherein: the upper end of the scraper (206) is tightly attached to the strong magnetic conveyor belt (203).

5. The screening apparatus for aluminum-iron alloy processing according to claim 3, wherein: a first colloid bin (301) is arranged right below the discharge end of the strong magnetic conveyor belt (203).

6. The screening apparatus for aluminum-iron alloy processing according to claim 4, wherein: the aluminum recovery device is characterized in that a first colloid bin (301) is placed inside an aluminum recovery bin (3), a filter screen (305) is arranged on the lower middle portion inside the aluminum recovery bin (3), a water outlet (306) is formed in the side wall of the aluminum recovery bin (3) at the lower end of the filter screen (305), a water pump (303) is installed on the outer wall of the aluminum recovery bin (3), one side of the water pump (303) is connected with a water delivery pipe (304), and a second colloid bin (302) is arranged below the water delivery pipe (304).

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