CN220610809U - Titanium powder production facility convenient to deironing - Google Patents

Abstract

The utility model discloses titanium powder production equipment convenient for iron removal, which comprises the following components: iron removal case, charging mechanism, belt scraper separation mechanism. The feeding mechanism is arranged on the iron removal box and comprises a material conveying box, a feeding port is connected between the material conveying box and the iron removal box, and one end of the feeding port, which is positioned in the iron removal box, is connected with a flow guide pipe. The belt type scraper separation mechanism is arranged in the iron removal box and comprises a permanent magnet feeding belt, the permanent magnet feeding belt is arranged above the baffle, a pair of tensioning conveying rollers are arranged in the permanent magnet feeding belt, a plurality of dredging rakes are arranged above the permanent magnet feeding belt, and a plurality of groups of scraping plates are arranged on one side, away from the dredging rakes, of the permanent magnet feeding belt. According to the utility model, through the arrangement of the belt type scraper separation mechanism, the titanium powder production equipment can fully remove and separate the iron-containing oxides in the titanium powder, and the high efficiency and stability of the titanium powder production equipment in separating and removing the iron-containing oxides in the titanium powder are improved.

Description

Titanium powder production facility convenient to deironing

Technical Field

The utility model belongs to the technical field of titanium powder production equipment, and particularly relates to titanium powder production equipment convenient for iron removal.

Background

The titanium powder is metal powder made of titanium, is silver gray irregular powder, is generally used in the fields of aerospace, spraying, metallurgy, fireworks and the like, is a good refractory metal material, and the conventional titanium powder production process mainly comprises the steps of raw material preparation, ore reduction, crushing and grinding, magnetic separation and classification, drying and the like.

The patent number is: the utility model patent of CN216678602U discloses titanium powder production equipment convenient to deironing, this application is through setting up the material conveying case, deironing case, the feed inlet, the support, the second connecting rod, the permanent magnet, the baffle, the scraper blade, the deflector, technical characteristics such as limiting plate, titanium powder discharge gate, the iron fillings export, fixing base and motor, when using, adsorb the iron-containing oxide that contains in the titanium powder through the permanent magnet, and scrape the iron-containing oxide that adsorbs in the permanent magnet outside through the relative motion of scraper blade and permanent magnet, thereby make can realize automatic absorption, the striking off, the collection operation to the iron fillings under the circumstances that need not shutdown equipment, solve traditional manual clearance iron fillings troublesome operation, the loaded down with trivial details problem of step.

As can be seen from the description and the drawings, the titanium powder production device in the application carries out batch conveying on the titanium powder conveyed into the blanking box through the mutual cooperation of the connecting rod, the rotary drum and the partition plate when in use, and the iron-containing oxide in the titanium powder is adsorbed and separated through the permanent magnet after the titanium powder conveyed in batches passes through the permanent magnet.

However, this titanium powder production facility is in the clearance closely related between the removal effect of iron-containing oxide in the titanium powder and permanent magnet and the limiting plate in the use, and when the clearance between permanent magnet and the limiting plate is less, the effect that the permanent magnet adsorbed the separation to iron-containing oxide in the titanium powder is better, but has easy jam, deironing inefficiency's shortcoming, and when the clearance between permanent magnet and the limiting plate is great, although improved the efficiency that adsorbs the separation to iron-containing oxide in the titanium powder, but the permanent magnet can not fully contact with the titanium powder that the material box falls, just so make the effect that iron-containing oxide in the titanium powder got rid of less.

In summary, the single permanent magnet, the limiting plate and the scraper are mutually matched, and although the iron-containing oxide in the titanium powder can be separated and removed, the effect and the stability of separating and removing the iron-containing oxide in the titanium powder are poor in the use process.

Therefore, in view of the above technical problems, it is necessary to provide a titanium powder production apparatus which is convenient for iron removal.

Disclosure of Invention

The utility model aims to provide titanium powder production equipment convenient for iron removal, which aims to solve the problems of poor effect and poor stability of the titanium powder production equipment in separating and removing iron-containing oxides in titanium powder.

In order to achieve the above object, an embodiment of the present utility model provides the following technical solution:

a titanium powder production facility that facilitates deferrization, comprising: iron removal case, charging mechanism, belt scraper separation mechanism.

The iron removing box is fixedly connected with a baffle plate, and the baffle plate divides the iron removing box into a blanking cavity and an iron removing cavity.

The feeding mechanism is arranged on the iron removal box and comprises a material conveying box, a feeding port is connected between the material conveying box and the iron removal box, and one end of the feeding port, which is positioned in the iron removal box, is connected with a flow guide pipe.

The belt type scraper separation mechanism is arranged in the iron removal box and comprises a permanent magnet feeding belt, the permanent magnet feeding belt is arranged above the baffle, a pair of tensioning conveying rollers are arranged in the permanent magnet feeding belt, a plurality of dredging rakes are arranged above the permanent magnet feeding belt, a plurality of groups of scraping plates are arranged on one side, away from the dredging rakes, of the permanent magnet feeding belt, and the scraping plates are located in the iron removal cavity.

Further, the below of deironing case is connected with titanium powder discharge gate and iron fillings discharge gate, titanium powder discharge gate is linked together with blanking chamber, the iron fillings discharge gate is linked together with the deironing chamber. The titanium powder separated in the blanking cavity is conveniently led out through the titanium powder discharge hole. And the scrap iron discharge hole is used for guiding out the iron-containing oxides separated from the iron removal cavity.

Further, a rotary drum is arranged in the material conveying box. The rotary drum plays roles in supporting, fixing and rotating driving the partition plates. The rotary drum is internally connected with a rotating shaft. The rotating shaft plays roles of supporting, fixing and rotating driving on the rotating drum. The outside fixedly connected with multiunit evenly distributed's division board of rotary drum. The materials added in the material conveying box are conveniently and uniformly discharged through the rotation of the plurality of groups of partition plates.

Further, a rotating shaft is fixedly connected in each of the pair of tensioning conveying rollers. The rotating shaft plays roles of supporting, fixing and rotating driving on the tensioning conveying roller. The outside of deironing case is equipped with driving motor, driving motor's output shaft and rotation axis transmission are connected. The driving motor plays a role in providing power, and is convenient for playing a role in rotationally driving the rotating shaft by controlling the operation of the driving motor.

Further, one side of the rotating shaft, which is positioned outside the iron removal box, is connected with a driving belt wheel. The driving belt wheel plays a role in transmitting the power of the rotating shaft. And a synchronous belt is sleeved on the outer side of the driving belt wheel. The synchronous belt plays a role in connecting the transmission belt pulley and the transmission belt pulley, so that the driving belt pulley rotates along with the rotation of the transmission belt pulley under the action of the synchronous belt. One side of the synchronous belt, which is far away from the transmission belt wheel, is connected with a driving belt wheel, and the driving belt wheel is in transmission connection with the rotating shaft. The driving belt wheel plays a role in rotating and driving the rotating shaft.

Further, a shrinkage limit box is arranged on the outer side of the material thinning rake. The shrinkage limit box plays a role in supporting and moving limiting on the buffer spring. And a buffer spring is connected between the material dredging harrow and the shrinkage limit box. The buffer spring plays a role in connecting the material dredging harrow and the shrinkage limit box, and is convenient for play a role in buffering, supporting and limiting the material dredging harrow through shrinkage and resetting of the buffer spring. The outer sides of the scraping plates are provided with supporting limit boxes. The supporting and limiting box plays a role in supporting and moving limiting on the scraping plate. And a supporting spring is connected between the scraping plate and the supporting limit box. The scraping plate is buffered, supported and limited by the shrinkage and the resetting of the supporting spring. And a fixed plate is connected between the supporting limit box and the iron removal box. The supporting and limiting box is supported and limited through the fixing plate.

Compared with the prior art, the utility model has the following advantages:

according to the utility model, through the arrangement of the belt type scraper separation mechanism, the titanium powder production equipment can fully remove and separate the iron-containing oxides in the titanium powder, and the high efficiency and stability of the titanium powder production equipment in separating and removing the iron-containing oxides in the titanium powder are improved.

Drawings

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

FIG. 1 is a side cross-sectional view of a titanium powder production facility for facilitating iron removal in accordance with one embodiment of the present utility model;

FIG. 2 is a schematic diagram of the structure of FIG. 1 at A;

FIG. 3 is a schematic view of the structure of FIG. 1 at B;

FIG. 4 is a front cross-sectional view of a titanium powder production facility for facilitating iron removal in accordance with an embodiment of the present utility model;

FIG. 5 is a schematic view of the structure of FIG. 4 at C;

fig. 6 is a perspective view of a titanium powder production apparatus for facilitating iron removal in accordance with an embodiment of the present utility model.

In the figure: 1. iron removal bin, 101, baffle, 102, blanking chamber, 103, iron removal chamber, 104, titanium powder outlet, 105, scrap iron outlet, 2, charging mechanism, 201, material delivery bin, 202, inlet, 203, draft tube, 204, drum, 205, spindle, 206, splitter plate, 3, belt type scraper separation mechanism, 301, permanent magnet feed belt, 302, tension conveyor roller, 303, dredge rake, 304, scraper, 305, spindle, 306, drive motor, 307, drive pulley, 308, timing belt, 309, drive pulley, 310, shrinkage stop box, 311, buffer spring, 312, support stop box, 313, support spring, 314, fixed plate.

Detailed Description

The present utility model will be described in detail below with reference to the embodiments shown in the drawings. The embodiments are not intended to limit the utility model, but structural, methodological or functional modifications from the embodiments are within the scope of the utility model.

The utility model discloses titanium powder production equipment convenient for iron removal, which is shown in fig. 1-6 and comprises the following components: iron removal case 1, charging mechanism 2, belt scraper separation mechanism 3.

Referring to fig. 1, a baffle 101 is fixedly connected in the iron removal box 1. The separation of the titanium powder and the iron-containing oxide separated in the iron removal box 1 is facilitated by the baffle 101. Baffle 101 divides iron removal box 1 into blanking chamber 102 and iron removal chamber 103.

Referring to fig. 1, a titanium powder discharge port 104 and an iron filings discharge port 105 are connected to the lower part of the iron removing box 1, the titanium powder discharge port 104 is communicated with the blanking cavity 102, and the iron filings discharge port 105 is communicated with the iron removing cavity 103. The titanium powder separated in the blanking cavity 102 is conveniently led out through the titanium powder discharging hole 104. The scrap iron discharging port 105 is used for guiding out the iron-containing oxides separated from the iron removing cavity 103.

Referring to fig. 1, a feeding mechanism 2 is provided on an iron removal box 1, and the feeding mechanism 2 includes a feed box 201. Facilitating the additive transport of the raw materials to be separated through the feed box 201. A feed inlet 202 is connected between the feed box 201 and the iron removal box 1. The feed inlet 202 plays a role of connecting the feed box 201 with the iron removal box 1, so that raw materials in the feed box 201 are conveniently conveyed into the iron removal box 1 along the feed inlet 202.

Referring to fig. 1-2, a flow guiding pipe 203 is connected to one end of the feed port 202 located in the iron removal box 1. The raw materials conveyed by the feed inlet 202 are conveniently guided by the guide pipe 203.

Referring to fig. 1, a drum 204 is provided in the feed box 201. The drum 204 serves as a support for the partition 206, both stationary and rotationally driven. A rotation shaft 205 is connected to the drum 204. The rotating shaft 205 plays a role in supporting, fixing and rotationally driving the drum 204.

Referring to fig. 1, a plurality of groups of partition plates 206 are fixedly connected to the outer side of the drum 204. Facilitating uniform discharge of the added material in the feed tank 201 by rotation of the multi-component baffle 206.

Referring to fig. 1 to 3, a belt-type scraper separation mechanism 3 is provided in an iron removal box 1. The separation of the iron-containing oxides in the raw material fed through the feed port 202 is facilitated by the belt scraper separation mechanism 3. The belt-type scraper separation mechanism 3 comprises a permanent magnet feeding belt 301, and the permanent magnet feeding belt 301 is arranged above the baffle 101. The permanent magnet feeding belt 301 plays a role in bearing and conveying the raw materials conveyed by the guide pipe 203. At the same time, the adsorption of the iron-containing oxide in the raw materials through the permanent magnet feeding belt 301 is facilitated.

Referring to fig. 1 to 3, a pair of tension conveying rollers 302 are provided in a permanent magnet feeding belt 301. The permanent magnet feeding belt 301 is supported in tension and controlled in movement by a pair of tension conveying rollers 302.

Referring to fig. 1 to 3, a rotary shaft 305 is fixedly connected to each of the pair of tension-carrying rollers 302. The rotation shaft 305 plays a role in supporting, fixing and rotationally driving the tension conveying roller 302.

Referring to fig. 4, a driving motor 306 is provided outside the iron removal box 1, and an output shaft of the driving motor 306 is in transmission connection with a rotation shaft 305. The drive motor 306 functions to provide motive power to facilitate the rotational drive of the rotational shaft 305 by controlling the operation of the drive motor 306.

Specifically, the drive motor 306 is commercially available and can be used as it is.

As shown in fig. 4, a transmission pulley 307 is connected to one side of the rotary shaft 305 outside the iron removal box 1. The pulley 307 serves to transmit the power of the rotation shaft 305.

As shown in fig. 4, a timing belt 308 is provided on the outer side of the pulley 307. The timing belt 308 serves to connect the transmission pulley 307 and the transmission pulley 307, so that the drive pulley 309 is rotated with the rotation of the transmission pulley 307 by the timing belt 308. A driving pulley 309 is connected to a side of the timing belt 308 away from the driving pulley 307, and the driving pulley 309 is in driving connection with the rotating shaft 205. The rotation shaft 205 is driven to rotate by the driving pulley 309.

Referring to fig. 1-5, a plurality of dredging rakes 303 are arranged above the permanent magnet feeding belt 301. The raw materials conveyed on the permanent magnet feeding belt 301 are uniformly dispersed in a mode that a plurality of material dispersing rakes 303 and the permanent magnet feeding belt 301 move relatively, so that the thickness of the raw materials conveyed on the permanent magnet feeding belt 301 is reduced, and the sufficiency of adsorbing and separating iron-containing oxides in the raw materials is improved.

Referring to fig. 1-3, a shrinkage limiting box 310 is arranged on the outer side of the dredging rake 303. The shrinkage limit box 310 plays a role in supporting and moving limit on the buffer spring 311.

Referring to fig. 1-3, a buffer spring 311 is connected between the material-thinning rake 303 and the shrinkage limit box 310. The buffer spring 311 plays a role in connecting the dredging harrow 303 with the shrinkage limit box 310, so that the dredging harrow 303 is convenient to buffer and support and limit through shrinkage and reset of the buffer spring 311.

Referring to fig. 1-3, a plurality of groups of scraping plates 304 are arranged on one side of the permanent magnet feeding belt 301 away from the material thinning rake 303, and the plurality of groups of scraping plates 304 are positioned in the iron removing cavity 103. The scrap iron adsorbed on the permanent magnet feeding belt 301 is convenient to scrape and separate through the mutual contact of the plurality of groups of scraping plates 304 and the permanent magnet feeding belt 301.

Referring to fig. 1-3, the outer sides of the plurality of scraping plates 304 are respectively provided with a supporting and limiting box 312. The supporting and limiting box 312 plays a role in supporting and limiting movement of the scraping plate 304. A supporting spring 313 is connected between the scraping plate 304 and the supporting limit box 312. The scraping plate 304 is buffered, supported and limited by the contraction and the resetting of the supporting spring 313. A fixing plate 314 is connected between the supporting limit box 312 and the iron removal box 1. The supporting and limiting functions of the supporting and limiting box 312 are achieved through the fixing plate 314.

In specific use, titanium powder with iron oxide is conveyed into the material conveying box 201, the rotation shaft 205 rotates anticlockwise under the cooperation of the driving motor 306, the driving belt wheel 307 and the synchronous belt 308 by controlling the operation of the driving motor 306, and the externally added titanium powder with iron oxide is uniformly conveyed by the rotation of the separation plate 206.

The titanium powder with the iron oxide conveyed in the conveying box 201 is conveyed to the permanent magnet conveying belt 301 along the feeding port 202 and the guide pipe 203, the titanium powder with the iron oxide is conveyed through the movement of the permanent magnet conveying belt 301, and in the conveying process, the titanium powder with the iron oxide can be uniformly scattered through the plurality of dredging rakes 303, so that the permanent magnet conveying belt 301 can fully adsorb the iron oxide contained in the titanium powder.

The titanium powder with iron-containing oxide moves along with the movement of the permanent magnet feeding belt 301, the titanium powder falls into the blanking cavity 102 under the action of gravity and is led out by the titanium powder discharging hole 104, the iron-containing oxide moves along with the movement of the permanent magnet feeding belt 301, the iron-containing oxide adsorbed on the surface of the permanent magnet feeding belt 301 is scraped by a plurality of groups of scraping plates 304, the scraped iron-containing oxide can be discharged from the scrap iron discharging hole 105, and the iron-containing oxide contained in the titanium powder can be fully separated and removed by the movement of the permanent magnet feeding belt 301.

The technical scheme shows that the utility model has the following beneficial effects:

according to the utility model, through the arrangement of the belt type scraper separation mechanism, the titanium powder production equipment can fully remove and separate the iron-containing oxides in the titanium powder, and the high efficiency and stability of the titanium powder production equipment in separating and removing the iron-containing oxides in the titanium powder are improved.

It will be evident to those skilled in the art that the utility model is not limited to the details of the foregoing illustrative embodiments, and that the present utility model may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the utility model being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment contains only one independent technical solution, and that such description is provided for clarity only, and that the technical solutions of the embodiments may be appropriately combined to form other embodiments that will be understood by those skilled in the art.

Claims (6)

1. Titanium powder production facility convenient to deironing, characterized by includes:

the iron removing device comprises an iron removing box (1), wherein a baffle plate (101) is fixedly connected in the iron removing box (1), and the baffle plate (101) divides the iron removing box (1) into a blanking cavity (102) and an iron removing cavity (103);

the feeding mechanism (2) is arranged on the iron removal box (1), the feeding mechanism (2) comprises a material conveying box (201), a feeding port (202) is connected between the material conveying box (201) and the iron removal box (1), and one end of the feeding port (202) positioned in the iron removal box (1) is connected with a flow guide pipe (203);

the belt type scraper separation mechanism (3) is arranged in the iron removal box (1), the belt type scraper separation mechanism (3) comprises a permanent magnet feeding belt (301), the permanent magnet feeding belt (301) is arranged above the baffle (101), a pair of tensioning conveying rollers (302) are arranged in the permanent magnet feeding belt (301), a plurality of material thinning rakes (303) are arranged above the permanent magnet feeding belt (301), a plurality of groups of scraping plates (304) are arranged on one side, away from the material thinning rakes (303), of the permanent magnet feeding belt (301), and the scraping plates (304) are arranged in the iron removal cavity (103).

2. The titanium powder production equipment convenient for iron removal according to claim 1, wherein a titanium powder discharge port (104) and an iron filings discharge port (105) are connected to the lower part of the iron removal box (1), the titanium powder discharge port (104) is communicated with the blanking cavity (102), and the iron filings discharge port (105) is communicated with the iron removal cavity (103).

3. The titanium powder production equipment convenient for iron removal according to claim 1, wherein a rotary drum (204) is arranged in the material conveying box (201), a rotating shaft (205) is connected in the rotary drum (204), and a plurality of groups of partition plates (206) which are uniformly distributed are fixedly connected on the outer side of the rotary drum (204).

4. A titanium powder production facility convenient to deironing according to claim 3, characterized in that, a pair of tensioning conveying roller (302) are interior fixedly connected with rotation axis (305), the outside of deironing case (1) is equipped with driving motor (306), the output shaft and the rotation axis (305) transmission of driving motor (306) are connected.

5. The titanium powder production equipment convenient for iron removal according to claim 4, wherein one side of the rotating shaft (305) positioned outside the iron removal box (1) is connected with a driving belt wheel (307), the outer side of the driving belt wheel (307) is sleeved with a synchronous belt (308), one side of the synchronous belt (308) far away from the driving belt wheel (307) is connected with a driving belt wheel (309), and the driving belt wheel (309) is in transmission connection with the rotating shaft (205).

6. The titanium powder production equipment convenient for iron removal according to claim 1, wherein a shrinkage limit box (310) is arranged on the outer side of the material-thinning rake (303), a buffer spring (311) is connected between the material-thinning rake (303) and the shrinkage limit box (310), a plurality of groups of support limit boxes (312) are arranged on the outer side of the material-scraping plates (304), a support spring (313) is connected between the material-scraping plates (304) and the support limit boxes (312), and a fixing plate (314) is connected between the support limit boxes (312) and the iron-removing box (1).