CN117206074A - Fine material mineral processing equipment for titanium ore exploitation processing - Google Patents

Abstract

The application relates to the technical field of mineral aggregate screening, in particular to fine aggregate beneficiation equipment for titanium ore exploitation processing. Comprises a base and a material taking assembly; the left part of the base is provided with a material transmission module for conveying ilmenite; the right part of the base is provided with a magnetic attraction transmission module with magnetism, and the position of the magnetic attraction transmission module is higher than that of the material transmission module; the material taking assembly is arranged on the right part of the base and can take down the iron ores sucked on the material conveying module. According to the application, through the arrangement of the material taking assembly, the iron ore on the magnetic absorption transmission module is absorbed on the material bearing plate by utilizing the strong magnetic block, the strong magnetic block is driven to descend to be separated from contact with the material bearing plate by the rodless cylinder, and the supporting legs are pressed downwards when the strong magnetic block descends continuously, so that the material bearing plate is inclined, the iron ore is poured into the material box, the material taking of the iron ore can be realized without contacting with the magnetic absorption transmission module, and the risk of scraping the magnetic absorption surface of the magnetic absorption transmission module is reduced.

Description

Fine material mineral processing equipment for titanium ore exploitation processing

Technical Field

The application relates to the technical field of mineral aggregate screening, in particular to fine aggregate beneficiation equipment for titanium ore exploitation processing.

Background

Titanium is a transition metal element with relatively active chemical properties, mainly exists in the form of ore such as rutile, ilmenite, anatase, titanomagnetite and the like in nature, and is one of important mineral resources in China. Titanium and its alloy have the advantages of excellent corrosion resistance, high temperature strength, low density, high strength, good toughness and fatigue resistance, etc., and can be widely used in the fields of aerospace, chemical industry, machinery, construction, medical treatment, etc.

Since titanium ore and iron ore are symbiotic, when titanium ore is mined, iron ore is mined together, the obtained ore is a mixture of titanium ore and iron ore, the titanium ore and iron ore are subsequently required to be screened, the titanium ore and iron ore are separated by a magnetic separation method due to the fact that the magnetization characteristics of the iron and the titanium in a magnetic field are different, firstly, the titanium ore is required to be crushed into proper granularity, then is sent into the magnetic field, usually a magnetic suction plate, the strength of the magnetic field is set in advance, iron in the titanium ore can be sucked, so that the titanium ore is reserved, ore dressing is completed, but most of iron ore adsorbed on the magnetic suction plate is scraped by a scraper, the scraper rubs on the magnetic suction plate repeatedly, the adsorption surface of the iron ore is damaged, the generated magnetic field is changed when serious, the effect of the iron ore is deteriorated, and ore dressing of the titanium ore and the iron ore is influenced.

Disclosure of Invention

In order to solve the technical problems in the prior art, the fine material beneficiation equipment for titanium ore exploitation processing is provided.

The technical scheme of the application is as follows: a fine mineral processing device for titanium ore exploitation processing comprises a base and a material taking assembly; the left part of the base is provided with a material transmission module for conveying ilmenite; the right part of the base is provided with a magnetic attraction transmission module with magnetism, and the position of the magnetic attraction transmission module is higher than that of the material transmission module; the material taking assembly set up in the base right part can be with iron ore of absorbing on the material transmission module is taken off, include: the material box is arranged at the right part of the base and is used for collecting the iron ores taken down from the material conveying module; the U-shaped frame is arranged on the base and can support other parts of the material taking assembly; the wedge-shaped scraping plate is fixedly arranged at the top of the U-shaped frame and can block iron ores adsorbed on the material conveying module; the material bearing plate is used for temporarily storing iron ores falling from the material conveying module and can be lifted between the two inner side walls of the U-shaped frame; two telescopic rods which are symmetrically and fixedly arranged on the U-shaped frame and the movable ends of which are rotationally connected with the material bearing plate; two supporting legs which are symmetrically arranged at the bottom of the material bearing plate in a rotating manner; two rodless cylinders symmetrically and fixedly arranged on two sides of the U-shaped frame; and the strong magnetic block is arranged between the two rodless cylinders in a sliding way and can suck the iron ore on the material transmission module downwards.

In one embodiment, a gap of 5mm-8mm exists between the wedge-shaped scraping plate and the conveyor belt surface of the magnetic attraction transmission module; the magnetic force of the strong magnetic block is stronger than that of the material transmission module; when the strong magnetic block slides downwards along the two rodless cylinders, the strong magnetic block contacts with the two supporting legs and presses downwards, so that the material bearing plate is inclined.

In one embodiment, two baffle plates are symmetrically arranged on the base, and the two baffle plates are attached to the material transmission module and the magnetic transmission module; the bottoms of the two baffle plates are positioned at the output end of the material transmission module and are fixedly provided with a discharge hopper together; the base is located the square hole that can place storage device has been seted up to department under the hopper.

In one of the embodiments, two striker plates left portion is provided with the material subassembly of throwing jointly, the material subassembly of throwing can assist the workman to throw mineral aggregate, includes: the mounting frame is fixedly arranged at the left parts of the two striker plates and is arranged as a double-layer mounting frame; the fixed mounting is in the upper strata of mounting bracket can make the unloading hopper of mineral aggregate evenly whereabouts.

In one embodiment, be provided with the blending subassembly on the mounting bracket, the blending subassembly can be even with the mineral aggregate stirring of throwing in, includes: the stirring cylinder is fixedly arranged on the lower layer of the mounting frame; the four-division mixing frames are positioned in the mixing drum, the rotating shafts penetrate through the front side and the rear side of the mixing drum and are rotationally connected with the mounting frame; and the transmission belt is arranged between the rotating shaft of the magnetic suction transmission module, which is positioned in front, and the rotating shaft of the four-division mixing frame.

In one embodiment, set up vibration subassembly on the material transfer module, vibration subassembly can be right mineral aggregate shakes on the material transfer module, includes: cams symmetrically arranged at the front end and the rear end of the rotating shaft at the front of the magnetic transmission module; guide seats symmetrically arranged on the front side and the rear side of the base and connected with the base in a sliding manner through springs; the vibrating plates are fixedly connected with all the guide seats and positioned in the material transmission module; the ejector rods are symmetrically arranged on the vibrating plate and can be matched with the cams.

In one embodiment, the ejector rod is located on a center line of the vibration plate perpendicular to the feeding direction of the material conveying module; the guide seats are at least four and symmetrically distributed on two sides of the ejector rod.

In one embodiment, the left parts of the two baffle plates are provided with scraping pieces, the scraping pieces incline along the output direction of the material conveying module, and when the material conveying module conveys mineral aggregate to pass through the scraping pieces, the mineral aggregate can be scraped by the scraping pieces.

In one embodiment, the left portion of the two striker plates is further provided with a blending assembly, and the blending assembly includes: the hollow block is fixedly arranged on the striker plate; a reel which is arranged on the striker plate at the rear of the position and is wound with a pull rope; the mixing frame slides out of the two hollow blocks and can scatter mineral aggregate on the material transmission module while sliding.

In one embodiment, the mixing assembly further comprises an elastic member, wherein the elastic member is arranged between the hollow block and the mixing frame at a front position, and the mixing frame is connected with the vibration plate in series by a pull rope on the winding wheel.

The beneficial effects are that: 1. according to the application, through the arrangement of the material taking assembly, the iron ore on the magnetic absorption transmission module is absorbed on the material bearing plate by utilizing the strong magnetic block, the strong magnetic block is driven by the rodless cylinder to descend to be separated from contact with the material bearing plate, and the supporting legs are pressed downwards when the strong magnetic block descends continuously, so that the material bearing plate is inclined, the iron ore is poured into the material box, the material taking of the iron ore can be realized without contacting with the magnetic absorption transmission module, and the risk of scraping the magnetic absorption surface of the magnetic absorption transmission module is reduced;

2. through the arrangement of the feeding component and the mixing component, the feeding is carried out by utilizing the blanking hopper, and the mineral aggregate which is put into the mixing drum is uniformly mixed by utilizing the four-way mixing frame, so that the feeding speed is uniform, and the ore and the iron ore can be better beneficiated subsequently;

3. through the arrangement of the vibration component, the cam is utilized to rotate and is matched with the guide seat for use, so that the ejector rod can be pushed up and moved in a reciprocating manner, the vibration plate can impact the material transmission module, and mineral aggregates on the material transmission module are uniformly mixed in a vibration manner;

4. through the setting of scraping material spare and mixing subassembly, utilize scraping material spare to strickle the mineral aggregate on the material transmission module to thickness unanimity to when vibrations board reciprocating motion, through stay cord pulling mixing frame reciprocating motion, further mix and scrape the mineral aggregate on the material transmission module and scatter, so that follow-up ore dressing to it.

Drawings

Fig. 1 shows a front view of the present application.

Fig. 2 shows a partial schematic structure of the present application.

Fig. 3 shows a schematic view of the structure of fig. 1 after changing the viewing angle.

Fig. 4 shows a schematic structural view of the take-off assembly of the present application.

Fig. 5 illustrates a bottom view of the take out assembly of the present application.

Fig. 6 shows a schematic structural view of the mixing assembly of the present application.

Fig. 7 shows a schematic structural view of the vibration assembly of the present application.

Fig. 8 shows a schematic view of fig. 7 in section.

Fig. 9 shows a schematic structural view of the mixing assembly of the present application.

In the reference numerals: the device comprises a base, a 11-baffle plate, a 12-discharge hopper, a 13-square hole, a 2-material transmission module, a 3-feeding assembly, a 31-mounting frame, a 32-discharge hopper, a 4-magnetic transmission module, a 5-material taking assembly, a 51-material box, a 52-U-shaped frame, a 53-wedge-shaped scraping plate, a 54-bearing plate, a 55-telescopic rod, a 56-supporting leg, a 57-strong magnet, a 58-rodless cylinder, a 6-stirring assembly, a 61-stirring cylinder, a 62-four-division stirring frame, a 63-driving belt, a 7-vibration assembly, a 71-cam, a 72-vibration plate, a 73-guiding seat, a 74-ejector rod, an 8-scraping piece, a 9-stirring assembly, a 91-winding wheel, a 92-hollow block, a 93-stirring frame and a 94-elastic piece.

Detailed Description

The following description of the embodiments of the present application will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present application, but not all embodiments. The following description of at least one exemplary embodiment is merely exemplary in nature and is in no way intended to limit the application, its application, or uses. All other embodiments, which can be made by those skilled in the art based on the embodiments of the application without making any inventive effort, are intended to be within the scope of the application.

Examples: a fine mineral processing device for titanium ore exploitation processing, as shown in fig. 1 and 2, comprises a base 1 and a material taking assembly 5; the left part of the base 1 is provided with a material transmission module 2, and the material transmission module 2 is used for conveying ilmenite materials; the right part of the base 1 is provided with a magnetic suction transmission module 4, the surface layer of a transmission belt of the magnetic suction transmission module 4 is provided with a magnetic suction layer, and the position of the magnetic suction transmission module is higher than that of the material transmission module 2, so that iron ores in ilmenite materials on the material transmission module 2 can be sucked;

as shown in fig. 1-5, the material taking assembly 5 is disposed on the right portion of the base 1 and located below the material conveying module 2, and can take down the iron ore adsorbed on the material conveying module 2, and includes: the material box 51, the material box 51 is placed on the right part of the base 1, and the iron ore taken down from the material conveying module 2 falls into the material box 51 for centralized storage; the U-shaped frame 52 is fixedly arranged at the right part of the base 1 through bolts and is used for supporting other parts of the material taking assembly 5; the wedge-shaped scraping plate 53 is fixedly arranged at the top of the U-shaped frame 52 through bolts, a gap of 6mm exists between the wedge-shaped scraping plate 53 and the conveyor belt surface of the magnetic attraction transmission module 4, and iron ores adsorbed on the material transmission module 2 can be blocked, but the iron ores are not directly contacted with the conveyor belt surface of the magnetic attraction transmission module 4; the material bearing plate 54, wherein the material bearing plate 54 can temporarily store the iron ore falling from the material conveying module 2 and can also lift between the two inner side walls of the U-shaped frame 52; the two telescopic rods 55 are symmetrically arranged on the U-shaped frame 52, and the top ends of the two telescopic rods 55 are rotationally connected with the material bearing plate 54, so that the lifting distance of the material bearing plate 54 can be controlled; the two supporting legs 56 are also arranged, the two supporting legs 56 are both rotatably arranged at the bottom of the material bearing plate 54, and the length of the supporting legs 56 is smaller than the length of the telescopic rod 55 after being fully stretched; the rodless air cylinders 58, wherein the rodless air cylinders 58 are symmetrically and vertically arranged on two sides of the U-shaped frame 52; the strong magnet 57, the strong magnet 57 can slide between two rodless cylinders 58, the strong magnet 57 is initially attached to the material bearing plate 54, the magnetic force of the strong magnet 57 is stronger than that of the material conveying module 2, the material bearing plate 54 can be penetrated, iron ore on the material conveying module 2 is sucked downwards onto the material bearing plate 54, and the strong magnet 57 can be contacted with two supporting legs 56 and pressed downwards when sliding downwards along the two rodless cylinders 58.

When the application is used for carrying out ore dressing operation on ilmenite, the ore is required to be placed at the left end of the material conveying module 2, the material conveying module 2 is used for conveying the ilmenite rightwards, when the material reaches the lower part of the magnetic attraction conveying module 4, iron ore in the ore is adsorbed by the magnetic attraction conveying module 4 and conveyed rightwards, the rest ore is discharged outwards from the material conveying module 2, when the magnetic attraction conveying module 4 conveys the iron ore to the upper part of the material box 51, the iron ore on the magnetic attraction conveying module 4 is downwards adsorbed to the material bearing plate 54 due to the action of the strong magnetic blocks 57, after the quantity of the iron ore on the material bearing plate 54 reaches a certain degree, the strong magnetic blocks 57 are driven to descend by the rodless air cylinders 58, the material bearing plate 54 will descend under the gravity of the iron ore and the iron ore, until the telescopic rod 55 is contracted to the shortest, the material bearing plate 54 cannot descend continuously, but the strong magnet 57 can descend continuously to contact with the supporting leg 56 and press down the supporting leg 56, so that the material bearing plate 54 inclines leftwards, and as the strong magnet 57 is far away from the material bearing plate 54, the suction force of the iron ore on the material bearing plate 54 is smaller than the gravity of the iron ore, the iron ore can fall into the material box 51 immediately for uniform storage, and in the process of pouring the iron ore on the material bearing plate 54 into the material box 51, the iron ore conveyed on the magnetic attraction transmission module 4 is blocked by the wedge-shaped scraping plate 53, and the iron ore is sucked after the strong magnet 57 ascends.

As shown in fig. 3 and 7, two baffle plates 11 are symmetrically and fixedly installed on the base 1 through bolts, the two baffle plates 11 are positioned between the material transmission module 2 and the magnetic attraction transmission module 4 and are attached to the surface of the two transmission belts, mineral aggregate can be isolated between the two baffle plates 11, and the mineral aggregate is prevented from leaking down from two sides of the material transmission module 2 and the magnetic attraction transmission module 4 in the conveying process; the hopper 12 is fixedly arranged at the bottom side of the two baffle plates 11 close to the output end of the material transmission module 2 through bolts, so that the titanium ore output from the material transmission module 2 can be guided; square holes 13 are formed in the position, right below the discharge hopper 12, of the base 1, and a worker can place the storage device in the square holes 13, so that mineral aggregates after ore dressing are stored in a concentrated mode.

As shown in fig. 1 and 3, the left parts of the two striker plates 11 are provided with a feeding assembly 3 together, and the feeding assembly 3 can assist workers in feeding mineral aggregate, and comprises: the mounting frame 31 is provided with two layers, and the mounting frame 31 is fixedly arranged at the left parts of the two striker plates 11 through bolts; and the lower hopper 32, the upper half part of the lower hopper 32 is square, and can store a certain amount of mineral aggregate, and the lower half part is funnel-shaped, so that the mineral aggregate can be uniformly thrown into the material transmission module 2.

As shown in fig. 1 and 6, be provided with mixing assembly 6 on the mounting bracket 31, mixing assembly 6 can stir the mineral aggregate of throwing in evenly, includes: the stirring barrel 61, the stirring barrel 61 is fixedly arranged on the lower layer of the mounting frame 31, the top is communicated with the discharging hopper 32, and the bottom is provided with a discharging hole; the four-division mixing frame 62, the four-division mixing frame 62 is positioned in the mixing drum 61, the rotating shaft of the four-division mixing frame 62 penetrates out of the mixing drum 61 and is rotationally connected with the mounting frame 31, mineral aggregate entering the mixing drum 61 can be uniformly mixed during rotation, and the mineral aggregate can be quantitatively taken out from a discharge hole of the mixing drum 61; the transmission belt 63, the transmission belt 63 winds around the rotation shaft of the magnetic suction transmission module 4 and the rotation shaft of the four-division mixing frame 62, and the magnetic suction transmission module 4 can drive the four-division mixing frame 62 to synchronously rotate when rotating.

After the mineral aggregate is thrown into the blanking hopper 32, the mineral aggregate is discharged into the stirring barrel 61 from the funnel-shaped part of the blanking hopper 32 at a constant speed, the magnetic suction transmission module 4 is operated and drives the four-division stirring frame 62 to rotate, the mineral aggregate falling into the stirring barrel 61 is stirred, and the inner space of the stirring barrel 61 is equally divided into four parts by the four-division stirring frame 62 due to the constant speed throwing of the mineral aggregate, so that the mineral aggregate falling into the material transmission module 2 is consistent in amount in unit time, and the uniform throwing of the mineral aggregate is realized.

As shown in fig. 1, 7 and 9, the material transmission module 2 is provided with a vibration component 7, and the vibration component 7 can shake mineral aggregate on the material transmission module 2, including: the cams 71, the cams 71 are fixedly arranged at the front and rear ends of the rotating shaft at the front of the magnetic transmission module 4, and the cams 71 rotate when the magnetic transmission module 4 operates; the four guide seats 73 are arranged, two guide seats 73 are respectively arranged at the front and the rear of the base 1 and are symmetrically distributed, and the guide seats 73 are connected with the base 1 in a sliding manner through springs; the vibration plate 72, the vibration plate 72 is located inside the material transmission module 2, and is fixedly connected with four guide seats 73; the two ejector pins 74 are fixedly arranged on the vibration plate 72, and are respectively in sliding contact with the nearest cams 71.

When the cam 71 rotates along with the magnetic attraction transmission module 4, the ejector rod 74 is pressed downwards when the protruding part of the cam contacts with the ejector rod 74, the vibration plate 72 descends along the guide seat 73, the spring between the guide seat 73 and the base 1 compresses the accumulated force, and after the cam 71 rotates to be out of contact with the ejector rod 74, the vibration plate 72 resets under the action of the spring and impacts the material transmission module 2 under inertia, so that mineral materials on the material transmission module 2 are scattered by vibration, and the follow-up suction of iron ores in the mineral materials is facilitated.

As shown in fig. 7 and 9, the left parts of the two baffle plates 11 are fixedly provided with scraping pieces 8 through bolts, the bottoms of the scraping pieces 8 incline rightwards, and mineral aggregate on the material conveying module 2 can be scraped by the scraping pieces 8 when passing through the scraping pieces 8, so that the thickness of the mineral aggregate on the material conveying module 2 is uniform after passing through the scraping pieces 8.

As shown in fig. 1 and 9, the left parts of the two striker plates 11 are further provided with a mixing assembly 9, and the mixing assembly 9 includes: the two hollow blocks 92 are arranged, one block is fixedly arranged on each of the two striker plates 11 and is positioned on the right side of the scraping piece 8; the reel 91, the reel 91 is installed on the striker plate 11 positioned at the back, the pull rope is wound on the striker plate, and the bottom end of the pull rope is connected with the vibration plate 72; the mixing frame 93 penetrates through the two hollow blocks 92, and a plurality of elliptic cylinders which can be in surface contact with the conveying belt of the material conveying module 2 are uniformly arranged on the mixing frame 93 and are connected with the top end of the pull rope; the elastic member 94, the elastic member 94 is an elastic rope, and is disposed between the hollow block 92 and the mixing rack 93 at a front position, and can pull the mixing rack 93 to reset.

When the vibration plate 72 reciprocates, under the combined action of the pull rope and the elastic piece 94 on the reel 91, the mixing frame 93 is pulled to reciprocate along the feeding direction of the vertical material conveying module 2, so that the mineral aggregate scraped by the scraping piece 8 slides, and the follow-up steps are facilitated.

It is noted that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of exemplary embodiments according to the present application. As used herein, the singular is also intended to include the plural unless the context clearly indicates otherwise, and furthermore, it is to be understood that the terms "comprises" and/or "comprising" when used in this specification are taken to specify the presence of stated features, steps, operations, devices, components, and/or combinations thereof.

The relative arrangement of the components and steps, numerical expressions and numerical values set forth in these embodiments do not limit the scope of the present application unless it is specifically stated otherwise. Meanwhile, it should be understood that the sizes of the respective parts shown in the drawings are not drawn in actual scale for convenience of description. Techniques, methods, and apparatus known to one of ordinary skill in the relevant art may not be discussed in detail, but are intended to be part of the specification where appropriate. In all examples shown and discussed herein, any specific values should be construed as merely illustrative, and not a limitation. Thus, other examples of the exemplary embodiments may have different values. It should be noted that: like reference numerals and letters denote like items in the following figures, and thus once an item is defined in one figure, no further discussion thereof is necessary in subsequent figures.

In the description of the present application, it should be understood that the azimuth or positional relationships indicated by the azimuth terms such as "front, rear, upper, lower, left, right", "lateral, vertical, horizontal", and "top, bottom", etc., are generally based on the azimuth or positional relationships shown in the drawings, merely to facilitate description of the present application and simplify the description, and these azimuth terms do not indicate and imply that the apparatus or elements referred to must have a specific azimuth or be constructed and operated in a specific azimuth, and thus should not be construed as limiting the scope of protection of the present application; the orientation word "inner and outer" refers to inner and outer relative to the contour of the respective component itself.

Spatially relative terms, such as "above … …," "above … …," "upper surface at … …," "above," and the like, may be used herein for ease of description to describe one device or feature's spatial location relative to another device or feature as illustrated in the figures. It will be understood that the spatially relative terms are intended to encompass different orientations in use or operation in addition to the orientation depicted in the figures. For example, if the device in the figures is turned over, elements described as "above" or "over" other devices or structures would then be oriented "below" or "beneath" the other devices or structures. Thus, the exemplary term "above … …" may include both orientations of "above … …" and "below … …". The device may also be positioned in other different ways (rotated 90 degrees or at other orientations) and the spatially relative descriptors used herein interpreted accordingly.

In addition, the terms "first", "second", etc. are used to define the components, and are only for convenience of distinguishing the corresponding components, and the terms have no special meaning unless otherwise stated, and therefore should not be construed as limiting the scope of the present application.

The above description is only of the preferred embodiments of the present application and is not intended to limit the present application, but various modifications and variations can be made to the present application by those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present application should be included in the protection scope of the present application.

Claims (10)

1. A fine mineral processing device for titanium ore exploitation processing comprises a base (1) and a material taking assembly (5); a material conveying module (2) for conveying ilmenite is arranged at the left part of the base (1); the right part of the base (1) is provided with a magnetic attraction transmission module (4) with magnetism, and the position of the magnetic attraction transmission module (4) is higher than that of the material transmission module (2);

the method is characterized in that: the material taking assembly (5) is arranged on the right part of the base (1), can take down the iron ore sucked on the material conveying module (2), and comprises: a material box (51) which is arranged at the right part of the base (1) and is used for collecting the iron ore taken down from the material conveying module (2); a U-shaped frame (52) mounted on the base (1) and capable of supporting other components of the take-out assembly (5); the wedge-shaped scraping plate (53) is fixedly arranged at the top of the U-shaped frame (52) and can block iron ores adsorbed on the material conveying module (2); a material bearing plate (54) for temporarily storing the iron ore falling from the material conveying module (2) and capable of lifting between the two inner side walls of the U-shaped frame (52); two telescopic rods (55) which are symmetrically and fixedly arranged on the U-shaped frame (52) and are rotatably connected with the material bearing plate (54) at the movable ends; two supporting legs (56) which are symmetrically arranged at the bottom of the material bearing plate (54) in a rotating manner; two rodless cylinders (58) symmetrically and fixedly arranged at two sides of the U-shaped frame (52); and a strong magnet (57) which is arranged between the two rodless cylinders (58) in a sliding manner and can suck the iron ore on the material conveying module (2) downwards.

2. A fine mineral processing apparatus for the production of titanium ore as claimed in claim 1, wherein: a gap of 5mm-8mm exists between the wedge-shaped scraping plate (53) and the conveyor belt surface of the magnetic suction transmission module (4); the magnetic force of the strong magnetic block (57) is stronger than that of the material transmission module (2); when the strong magnetic blocks (57) slide downwards along the two rodless cylinders (58), the strong magnetic blocks are contacted with the two supporting legs (56) and are pressed downwards, so that the material bearing plate (54) is inclined.

3. A fine mineral processing apparatus for the production of titanium ore as claimed in claim 2, wherein: two material blocking plates (11) are symmetrically arranged on the base (1), and the two material blocking plates (11) are attached to the material transmission module (2) and the magnetic transmission module (4); the bottoms of the two baffle plates (11) are positioned at the output end of the material transmission module (2) and fixedly provided with a discharge hopper (12); the square hole (13) capable of placing the storage device is formed in the position, right below the discharging hopper (12), of the base (1).

4. A fine mineral processing apparatus for the production of titanium ore as claimed in claim 3, wherein: the left part of two striker plates (11) is provided with jointly and throws material subassembly (3), throw material subassembly (3) can assist the workman to throw mineral aggregate, include: the mounting frame (31) is fixedly arranged at the left parts of the two striker plates (11) and is arranged as a double layer; and a discharging hopper (32) which is fixedly arranged on the upper layer of the mounting frame (31) and can enable mineral aggregate to uniformly fall down.

5. A fine mineral processing apparatus for the production of titanium ore as claimed in claim 4, wherein: be provided with mixing subassembly (6) on mounting bracket (31), mixing subassembly (6) can be even with the mineral aggregate stirring of throwing in, include: a stirring cylinder (61) fixedly arranged on the lower layer of the mounting frame (31); the four-division mixing frames (62) are positioned in the mixing drum (61), the rotating shafts penetrate through the front side and the rear side of the mixing drum (61) and are rotationally connected with the mounting frame (31); and the transmission belt (63) is arranged between the rotating shaft of the magnetic suction transmission module (4) and the rotating shaft of the four-division mixing frame (62).

6. A fine mineral processing apparatus for the production of titanium ore as claimed in claim 5, wherein: set up vibration subassembly (7) on material transmission module (2), vibration subassembly (7) can be right mineral aggregate shakes on material transmission module (2), include: cams (71) symmetrically arranged at the front end and the rear end of the rotating shaft at the front position of the magnetic transmission module (4); guide seats (73) symmetrically arranged on the front side and the rear side of the base (1) and connected with the base (1) in a sliding manner through springs; simultaneously, the vibrating plates (72) are fixedly connected with all the guide seats (73) and positioned in the material transmission module (2); and ejector rods (74) symmetrically arranged on the vibrating plate (72) and capable of being matched with the cam (71).

7. A fine mineral processing apparatus for the production of titanium ore as claimed in claim 6, wherein: the ejector rod (74) is positioned on the central line of the vibrating plate (72) perpendicular to the feeding direction of the material conveying module (2); the guide seats (73) are at least provided with four, and are symmetrically distributed on two sides of the ejector rod (74).

8. A fine mineral processing apparatus for the production of titanium ore as claimed in claim 7, wherein: the left part of the two baffle plates (11) is provided with a scraping part (8), the scraping part (8) inclines along the output direction of the material conveying module (2), and when mineral aggregate is conveyed by the material conveying module (2) to pass through the scraping part (8), the mineral aggregate can be scraped by the scraping part (8).

9. A fine mineral processing apparatus for the production of titanium ore as claimed in claim 8, wherein: the left part of two striker plates (11) still is provided with mixing subassembly (9), mixing subassembly (9) include: a hollow block (92) fixedly arranged on the striker plate (11); a reel (91) which is arranged on the striker plate (11) at the rear of the position and is wound with a pull rope; and the mixing rack (93) slides out of the two hollow blocks (92) and can scatter mineral aggregate on the material conveying module (2) while sliding.

10. A fine mineral processing apparatus for the production of titanium ore as claimed in claim 9, wherein: the mixing assembly (9) further comprises an elastic piece (94), the elastic piece (94) is arranged between the hollow block (92) and the mixing frame (93) at the front position, and the mixing frame (93) is connected with the vibration plate (72) in series by a pull rope on the reel (91).