CN116532220B - Titanium dioxide production crushing apparatus - Google Patents

Abstract

The invention discloses titanium dioxide production crushing equipment, which belongs to the technical field of titanium dioxide production equipment and comprises a machine case, a pushing mechanism, a material pressing disc, a dispersing cover, a movable millstone, a grinding table and a driving motor, wherein the driving motor is fixedly connected to the bottom of the machine case, a feeding hopper is fixedly arranged at the top of the machine case, a discharge hole is arranged at the bottom of the machine case, a driving shaft is fixedly connected to a rotating shaft of the driving motor, the dispersing cover, the movable millstone and the grinding table are sequentially and fixedly connected to the driving shaft from top to bottom, the material pressing disc is arranged between the dispersing cover and the movable millstone, the driving shaft penetrates through the material pressing disc, a gap is arranged between the material pressing disc and the driving shaft, the pushing mechanism is arranged on one side of the material pressing disc and one side of the movable millstone, and the pushing mechanism is in sliding connection with the machine case. The crushing equipment provided by the invention is subjected to multistage crushing, so that the produced titanium dioxide powder is finer and finer, and the crushing efficiency of the titanium dioxide is higher.

Description

Titanium dioxide production crushing apparatus

Technical Field

The invention relates to the technical field of titanium dioxide production equipment, in particular to titanium dioxide production crushing equipment.

Background

Titanium dioxide is widely used in the industries of paint, plastics, paper, printing ink, chemical fiber, rubber, cosmetics and the like. It has high melting point and is also used for making refractory glass, glaze, enamel, pottery clay, high-temp. resistant experiment utensils, etc. Titanium dioxide may be obtained from the acid decomposition extraction of rutile or from the decomposition of titanium tetrachloride.

Titanium dioxide is widely used, titanium dioxide is required to be in a finer powder shape in application generally, traditional titanium dioxide crushing equipment is mainly used for crushing once, such as a crushing device for titanium dioxide production disclosed in the publication No. CN113559981B, the titanium dioxide can be crushed efficiently under the telescopic adjustment action of the adjusting component through the running fit of the thrust component and the crushing component, but the once-crushing equipment wants to crush solid titanium dioxide into finer powder, and the crushing equipment needs great power and longer crushing time, and has high equipment requirement, and crushed titanium dioxide is crushed again after being screened, so that the operation is troublesome and the production efficiency is low. Secondly, titanium dioxide powder is generally adhered to the working surface of the crushing mechanism of the traditional titanium dioxide crushing device, and along with continuous crushing work, the more the powder is accumulated, the work of the crushing mechanism is affected, and when the machine is stopped for cleaning, time and labor are consumed. Finally, when the traditional titanium dioxide crushing equipment needs to be sampled and detected, fixed point sampling detection is usually set, so that the crushing effect of titanium dioxide cannot be comprehensively monitored, the quality of produced products is improved, and the production management of enterprises is not facilitated.

Disclosure of Invention

Aiming at the problems in the prior art, the invention aims to provide a titanium dioxide production crushing device which can crush titanium dioxide in multiple stages, and has good crushing effect and high crushing efficiency.

In order to solve the problems, the invention adopts the following technical scheme:

the utility model provides a titanium dioxide production crushing apparatus, includes quick-witted case, pushing equipment, swage disc, dispersion cover, moves mill, grinding table, driving motor fixed connection is in quick-witted case bottom, the quick-witted case top is fixedly provided with the feeder hopper, the quick-witted case bottom is provided with the discharge gate, fixedly connected with drive shaft in the driving motor pivot, from the top down fixedly connected with dispersion cover, moves mill, grinding table in proper order in the drive shaft, the swage disc sets up between dispersion cover and moves mill, the drive shaft runs through the swage disc, be provided with the gap between swage disc and the drive shaft, the swage equipment sets up in swage disc and moves mill one side;

the utility model discloses a quick-witted case, including quick-witted case, feeder hopper below is provided with dispersion chamber, a plurality of spacing posts of pressure charging tray top surface edge equidistance fixedly connected with, dispersion chamber bottom corresponds spacing post department and is provided with spacing hole, the cover has put the spring on the spacing post, spring bottom and pressure charging tray fixed connection, spring top and dispersion chamber bottom fixed connection, pushing equipment and quick-witted case sliding connection, pushing equipment stretches into quick-witted incasement one end and rotates and be connected with the arc and push away the flitch, arc pushes away flitch top fixedly connected with ejector pad on the pushing equipment.

As a preferable scheme of the invention, a first limiting plate is fixedly connected to a pushing mechanism in the case, a second limiting plate is fixedly connected to a pushing mechanism outside the case, a sliding block is arranged between the first limiting plate and the second limiting plate, a sliding groove is arranged on the case corresponding to the sliding block, the sliding block is in sliding connection with the sliding groove, a half gear is fixedly connected to the arc pushing plate, the half gear is rotationally connected with the pushing mechanism, a driving gear is rotationally connected to one side, far away from the arc pushing plate, of the upper half gear of the pushing mechanism, the driving gear is meshed with the half gear, a first driving wheel is fixedly connected to the bottom of the driving gear, a motor seat is fixedly connected to the outer side of the second limiting plate, a control motor is fixedly connected to the motor seat, a second driving wheel is fixedly connected to the bottom of a rotating shaft of the control motor, and the first driving wheel is connected with the second driving wheel through a driving chain.

As a preferable scheme of the invention, a working cavity is arranged below the dispersing cavity, a grinding cavity is arranged below the working cavity, a collecting cavity is arranged below the grinding cavity, a discharge hole is arranged at the bottom of the collecting cavity, a supporting column is fixedly connected to the bottom of the case, a fixed disc is fixedly connected to the driving motor, the fixed disc is fixedly connected with the supporting column, the dispersing cover is arranged right below a feeding hopper in the dispersing cavity, the pushing mechanism, the pressing disc and the movable grinding disc are arranged in the working cavity, and the grinding table is arranged in the grinding cavity.

As a preferable scheme of the invention, sampling heads are fixedly connected to the two ends of the upper inner side of the arc-shaped pushing plate, the sampling heads are communicated with sampling pipes, the sampling pipes comprise arc-shaped pipes, telescopic hoses and connecting pipes, the arc-shaped pipes are fixedly connected to the outer sides of the arc-shaped pushing plate, the connecting pipes penetrate through the first limiting plate, the sliding block and the second limiting plate and extend out of the chassis, one ends of the telescopic hoses are communicated with the arc-shaped pipes, and the other ends of the telescopic hoses are communicated with the connecting pipes.

As a preferable scheme of the invention, the top surface of the material pressing disc is of an inverted cone structure.

As a preferable scheme of the invention, the bottom edge of the pressing plate is provided with an inclined plane, and the inclined plane of the bottom edge of the pressing plate is parallel to the inclined plane of the pushing block.

As a preferable scheme of the invention, the top surface and the bottom surface of the movable millstone are both provided with inclined surfaces, the bottom of the working cavity is provided with a material blocking ring, and one side of the material blocking ring, which is close to the movable millstone, is provided with an inclined surface.

As a preferable scheme of the invention, the end of the connecting pipe extending out of the case is provided with threads.

As a preferable scheme of the invention, the grinding table is a round table with a small top and a large bottom, and the inner diameter of the grinding cavity is larger than the bottom diameter of the grinding table.

As a preferable scheme of the invention, a plurality of bulges are equidistantly arranged on the inner wall of the grinding cavity.

3. Advantageous effects

Compared with the prior art, the invention has the advantages that:

(1) In this scheme solid titanium dioxide gets into dispersion intracavity from the feeder hopper, drop on the dispersion cover, the dispersion cover is driven rotatablely by driving motor, make fixed titanium dioxide pass through dispersion cover rebound scattering, with dispersion cover and dispersion intracavity wall collision, preliminary crushing is carried out, reduce the great solid titanium dioxide of volume, make things convenient for follow-up crushing, solid titanium dioxide after preliminary crushing falls on pressing the charging tray top surface, then get into pressing the charging tray through pressing the clearance between charging tray and the drive shaft and move between the mill, driving motor drives and moves the mill and rotate and smashes the titanium dioxide, the titanium dioxide after smashing is got rid of to moving the mill edge owing to the centrifugal effect, finally fall the grinding table and grind the space between the chamber, the grinding table is rotatory smashes again titanium dioxide, finally smash the titanium dioxide that ends gets into the intracavity that gathers materials, finally discharge gate discharge machine case outside, solid titanium dioxide smashes step by step many times, not only smash evenly, smash effectually, also do not need longer crushing time when smashing every stage smash, smash efficiency is high.

(2) In this scheme, because pushing equipment and quick-witted case sliding connection for pushing equipment can be in the horizontal direction displacement, pushing equipment can drive the arc and push away the flitch and get into between the gland plate and the movable millstone in the horizontal direction displacement, the movable millstone continues to rotate, arc pushes away flitch bottom and movable millstone top surface laminating, arc pushes away the flitch bottom and is provided with the slope, make arc push away the flitch and scrape the titanium dioxide powder of adhesion on movable millstone surface, the accessible transmission chain drives the drive gear rotation, thereby drive half gear rotation, then make arc push away the rotatable angle of adjustment, make arc push away the flitch can all scrape the titanium dioxide of movable millstone surface everywhere adhesion from axle center to edge position promptly, prevent that the powder can be accumulated more, influence crushing equipment's work, lead to the shut down clearance, thereby mistake work efficiency.

(3) When the sampling head gets into between the gland plate and the movable millstone along with the arc pushing plate in this scheme, the arc pushing plate begins to push away the material, and the titanium dioxide that the arc pushing plate pushed up is piled up to the arc pushing plate the place ahead for in the sampling head inserts the deposited titanium dioxide, make things convenient for the sampling head to draw the sample through the sampling tube, and because the rotatable angle regulation of arc pushing plate, it moves each position of millstone axle center to edge to make the sampling head arrive when the angle regulation is rotated along with the arc pushing plate, make things convenient for the sampling head to extract the sample of different positions at random, but comprehensive monitoring titanium dioxide's crushing effect, and production product quality.

Drawings

FIG. 1 is a schematic view of a titanium dioxide production crushing apparatus according to the present invention;

FIG. 2 is a partial cross-sectional view of a titanium dioxide production crushing apparatus of the present invention;

FIG. 3 is a schematic view of the structure of a removal housing of a titanium dioxide production crushing apparatus of the present invention;

FIG. 4 is a schematic structural view of a pushing mechanism of a titanium dioxide production crushing apparatus according to the present invention;

FIG. 5 is an enlarged view of a portion of the titanium dioxide production crushing apparatus of the present invention at A in FIG. 4;

FIG. 6 is a schematic view showing the structure of a titanium dioxide production crushing apparatus according to another aspect of the present invention;

FIG. 7 is a schematic view of another angle of a pushing mechanism of a titanium dioxide production crushing apparatus according to the present invention;

FIG. 8 is an enlarged view of a portion at B in FIG. 7 of a titanium dioxide production crushing apparatus of the present invention.

The reference numerals in the figures illustrate:

1. a chassis; 2. a pushing mechanism; 3. pressing a material tray; 4. a dispersion cover; 5. a movable millstone; 6. a grinding table; 7. a driving motor; 11. a feed hopper; 12. a dispersion chamber; 13. a working chamber; 14. a grinding chamber; 15. a collection chamber; 16. a support column; 21. a pushing block; 22. an arc-shaped pushing plate; 23. a slide block; 24. controlling a motor; 25. a drive gear; 26. a sampling head; 221. a half gear; 231. a first limiting plate; 232. a second limiting plate; 241. a motor base; 242. a second driving wheel; 251. a first driving wheel; 261. an arc tube; 262. a flexible hose; 263. a connecting pipe; 71. a drive shaft; 72. a fixed disk.

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. It is apparent that the described embodiments are only some embodiments of the present invention, not all embodiments, and that all other embodiments obtained by persons of ordinary skill in the art without making creative efforts based on the embodiments in the present invention are within the protection scope of the present invention.

In the description of the present invention, it should be noted that the positional or positional relationship indicated by the terms such as "upper", "lower", "inner", "outer", "top/bottom", etc. are based on the positional or positional relationship shown in the drawings, are merely for convenience of describing the present invention and simplifying the description, and do not indicate or imply that the apparatus or elements referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

Examples:

referring to fig. 1-8, a titanium dioxide production crushing device comprises a case 1, a pushing mechanism 2, a material pressing disc 3, a dispersing cover 4, a movable millstone 5, a grinding table 6 and a driving motor 7, wherein the driving motor 7 is fixedly connected to the bottom of the case 1, a feeding hopper 11 is fixedly arranged at the top of the case 1, a discharging hole is arranged at the bottom of the case 1, a driving shaft 71 is fixedly connected to a rotating shaft of the driving motor 7, the dispersing cover 4, the movable millstone 5 and the grinding table 6 are sequentially and fixedly connected to the driving shaft 71 from top to bottom, the material pressing disc 3 is arranged between the dispersing cover 4 and the movable millstone 5, the driving shaft 71 penetrates through the material pressing disc 3, a gap is arranged between the material pressing disc 3 and the driving shaft 71, and the pushing mechanism 2 is arranged at one side of the material pressing disc 3 and the movable millstone 5;

the utility model discloses a feeding hopper, including chassis 1, pushing mechanism 2 and chassis 1, pushing mechanism 2 is connected with arc pushing plate 22 in the one end rotation of stretching into chassis 1, pushing mechanism 2 is gone up arc pushing plate 22 top fixedly connected with ejector pad 21, and the spacing hole is provided with to the spacing post 31 department of 3 top edges equidistance fixedly connected with of chassis 1, spring 32 has been put to spacing post 31 upper cover.

In this embodiment, driving motor 7 can drive dispersion hood 4, move mill 5, grinding table 6 rotation work, solid titanium dioxide gets into quick-witted case 1 from feeder hopper 11, fall into on the pressure charging tray 3 after dispersing through dispersion hood 4, then get into between pressure charging tray 3 and the mill 5 through the clearance between pressure charging tray 3 and the drive shaft 71 and smash, the titanium dioxide after smashing is thrown to the mill 5 edge because of centrifugal effect, finally fall to the space between grinding table 6 and quick-witted case 1, grinding table 6 rotation smashes the titanium dioxide again, finally the titanium dioxide after smashing is discharged out of machine case 1 from the discharge gate, and pushing equipment 2 can stretch into between pressure charging tray 3 and the mill 5, scrape the material for the mill 5, prevent titanium dioxide powder adhesion on the mill 5, and because grinding table 6 is the frustum formula and is high-speed extrusion collision smashing, and vertical smashing, finally the titanium dioxide powder can all be discharged from the discharge gate through gravity.

The pushing mechanism 2 can be equidistantly arranged in the same horizontal plane, as the pushing mechanism 2 is in sliding connection with the chassis 1, an operator is used for pushing the pushing mechanism by hand or an electric push rod is used for pushing the pushing mechanism, so that the pushing mechanism 2 can move in the horizontal direction, the arc pushing plate 22 can be driven to enter between the pressing plate 3 and the movable grinding disc 5 by the displacement of the pushing mechanism 2 in the horizontal direction, an inclined plane is arranged on one side, close to the pressing plate 3, of the pushing block 21, so that when the pushing mechanism 2 drives the arc pushing plate 22 to enter between the pressing plate 3 and the movable grinding disc 5, the pushing block 21 extrudes the pressing plate 3 to give an upward component force to the pressing plate, a plurality of limit columns 31 are fixedly connected to the edge of the top surface of the pressing plate 3 at equal intervals, limit columns 31 are arranged at positions corresponding to the limit columns 31 at the bottom of the dispersing cavity 12, springs 32 are fixedly connected with the pressing plate 3, the limit columns 31 are upwards displaced in the limit holes, so that gaps between the pressing plate 3 and the movable grinding disc 5 are large, and the pressing plate 22 between the pressing plate 3 and the movable grinding disc 5 can be conveniently pushed by the titanium dioxide;

firstly, when the arc-shaped material pushing plate 22 moves inwards along with the pushing mechanism 2 horizontally, the edge of the titanium dioxide driven millstone 5 between the material pressing disc 3 and the movable millstone 5 is pushed towards the center of the movable millstone 5, so that the titanium dioxide which just enters between the material pressing disc 3 and the movable millstone 5 and moves towards the edge of the movable millstone 5 due to extrusion is moved towards the center of the movable millstone 5 again to be piled up, the crushing effect is improved again, the arc-shaped material pushing plate 22 can be pushed inwards again after being retracted along with the pushing mechanism 2, and the titanium dioxide new and old materials which enter between the material pressing disc 3 and the movable millstone 5 at different time can be mixed through the material pushing process for a plurality of times, so that the crushing uniformity is improved;

secondly, the pushing mechanism 2 is circularly pushed inwards and outwards, so that the pushing mechanism 2 can be shifted in a reciprocating manner in the horizontal direction, the pushing block 21 on the pushing mechanism 2 can drive the pressing disc 3 to move up and down in a reciprocating manner, the pressing disc 3 can generate periodic vibration, firstly, the arc-shaped pushing plate is matched to push the edge of the titanium dioxide between the pressing disc 3 and the movable disc 5 to the center of the movable disc 5, the titanium dioxide which just enters between the pressing disc 3 and the movable disc 5 and moves to the edge of the movable disc 5 due to extrusion is enabled to move and accumulate to be higher toward the center of the movable disc 5 again, the titanium dioxide between the pressing disc 3 and the movable disc 5 can be periodically pressed by the pressing disc 3, the crushing effect is improved, and secondly, the titanium dioxide on the top surface of the pressing disc 3 can be accelerated by the periodic vibration enters between the pressing disc 3 and the movable disc 5, and excessive titanium dioxide is prevented from being accumulated on the top surface of the pressing disc 3;

finally, as the arc-shaped pushing plate 22 is rotationally connected with the pushing mechanism 2, the angle of the arc-shaped pushing plate 22 can be adjusted, so that the arc-shaped pushing plate 22 can push the titanium dioxide between the material pressing disc and the movable grinding disc 5 to different directions through the angle adjustment, and the titanium dioxide between the material pressing disc 3 and the movable grinding disc 5 is fully mixed.

Specifically, a first limiting plate 231 is fixedly connected to the pushing mechanism 2 in the chassis 1, a second limiting plate 232 is fixedly connected to the pushing mechanism 2 in the chassis 1, a sliding block 23 is arranged between the first limiting plate 231 and the second limiting plate 232, a sliding groove is arranged on the chassis 1 corresponding to the sliding block 23, the sliding block 23 is slidably connected with the sliding groove, a half gear 221 is fixedly connected to the arc pushing plate 22, the half gear 221 is rotatably connected with the pushing mechanism 2, a driving gear 25 is rotatably connected to one side, away from the arc pushing plate 22, of the upper half gear 221 of the pushing mechanism 2, the driving gear 25 is meshed with the half gear 221, a first driving wheel 251 is fixedly connected to the bottom of the driving gear 25, a motor base 241 is fixedly connected to the outer side of the second limiting plate 232, a control motor 24 is fixedly connected to the bottom of a rotating shaft of the control motor 24, and the first driving wheel 251 is connected with the second driving wheel 242 through a transmission chain.

In this embodiment, the pushing mechanism 2 is slidably connected to the chassis 1 through the cooperation of the sliding block 23 and the sliding groove, and the control motor 24 can rotate forward or reverse, because the arc pushing plate 22 is fixedly connected with the half gear 221, the half gear 221 is rotationally connected with the pushing mechanism 2, one side of the upper half gear 221 of the pushing mechanism 2 away from the arc pushing plate 22 is rotationally connected with the driving gear 25, the driving gear 25 is meshed with the half gear 221, the bottom of the driving gear 25 is fixedly connected with the first driving wheel 251, the bottom of the rotating shaft of the control motor 24 is fixedly connected with the second driving wheel 242, and the first driving wheel 251 is connected with the second driving wheel 242 through a driving chain, so that the control motor 24 can drive the driving gear 25 to rotate through the driving chain, thereby driving the half gear 221 to rotate, and further enabling the arc pushing plate 22 to rotationally adjust the angle;

when the arc pushing plate 22 enters between the material pressing disc 3 and the movable millstone 5, the movable millstone 5 continuously rotates, the arc pushing plate 22 is attached to the top surface of the movable millstone 5, a slope is arranged at the bottom of the arc pushing plate 22, so that the arc pushing plate 22 scrapes titanium dioxide powder adhered to the surface of the movable millstone 5, and then the arc pushing plate 22 is matched with the arc pushing plate 22 to rotate for adjusting an angle, so that the arc pushing plate 22 can be contacted with the movable millstone 5 from the axis to the edge position, namely, the arc pushing plate 22 can scrape all titanium dioxide adhered to the surface of the movable millstone 5, so that the more the powder is prevented from accumulating, the work of a crushing mechanism is influenced, the shutdown cleaning is caused, and the work efficiency is delayed;

simultaneously, the arc-shaped pushing plate 22 can push scraped titanium dioxide to the edge of the movable millstone 5 through adjusting the angle, so that the titanium dioxide can conveniently fall into the grinding cavity 14.

Specifically, dispersion chamber 12 below is provided with working chamber 13, the working chamber 13 below is provided with grinds chamber 14, it is provided with the chamber 15 that gathers materials to grind chamber 14 below, it is provided with the discharge gate to gather materials chamber 15 bottom, quick-witted case 1 bottom fixedly connected with support column 16, fixedly connected with fixed disk 72 on the driving motor 7, fixed disk 72 and support column 16 fixed connection, dispersion cover 4 sets up under the feeder hopper 11 in dispersion chamber 12, pushing equipment 2, swager 3, movable millstone 5 set up in working chamber 13, grinding table 6 sets up in grinding chamber 14.

In this embodiment, solid titanium dioxide gets into dispersion chamber 12 from feeder hopper 11, drop on dispersion hood 4, dispersion hood 4 is rotated by driving motor 7, make fixed titanium dioxide pass through dispersion hood 4 rebound scattering, collide with dispersion hood 4 and dispersion chamber 12 inner wall, carry out preliminary crushing, reduce the great solid titanium dioxide of volume, make things convenient for follow-up crushing, solid titanium dioxide after preliminary crushing falls on the pressure charging tray 3 top surface, then get into pressure charging tray 3 through the clearance between pressure charging tray 3 and the drive shaft 71 and move between the mill 5, driving motor 7 drives and moves mill 5 rotation and smashes the titanium dioxide, the titanium dioxide after smashing is thrown to moving mill 5 edge because of the centrifugal effect, finally fall to the space between grinding table 6 and the grinding chamber 14, grinding table 6 is rotatory smashes the titanium dioxide again, finally, the titanium dioxide after smashing gets into in the chamber 15 of gathering, finally, drop on fixed disk 72 through discharge gate discharge machine case 1 outward, can collect the titanium dioxide powder from fixed disk 72, also can gather the titanium dioxide powder after the material pipe is conveniently collected to the side connection row of chamber 15, the solid is smashed, but even, high-efficient crushing is needed in each time smashing step by step, high-efficient smashing is carried out.

Specifically, the sampling head 26 is fixedly connected to two ends of the upper inner side of the arc pushing plate 22, the sampling head 26 is communicated with a sampling tube, the sampling tube comprises an arc tube 261, a telescopic hose 262 and a connecting tube 263, the arc tube 261 is fixedly connected to the outer side of the arc pushing plate 22, the connecting tube 263 penetrates through the first limiting plate 231, the sliding block 23 and the second limiting plate 232 and extends out of the chassis 1, one end of the telescopic hose 262 is communicated with the arc tube 261, and the other end of the telescopic hose 262 is communicated with the connecting tube 263.

In this embodiment, when the sampling head 26 enters between the pressing disc 3 and the movable millstone 5 along with the arc-shaped material pushing plate 22, the arc-shaped material pushing plate 22 starts to push materials, titanium dioxide pushed by the arc-shaped material pushing plate 22 is piled up in front of the arc-shaped material pushing plate 22, so that the sampling head 26 is inserted into the piled titanium dioxide, the sampling head 26 can conveniently extract samples through the sampling tube, and the arc-shaped material pushing plate 22 can be rotated to adjust angles, so that the sampling head 26 can reach each position from the axis of the movable millstone 5 to the edge when the arc-shaped material pushing plate 22 rotates to adjust angles, the sampling head 26 can conveniently randomly extract samples at different positions, and the telescopic hose 262 in the sampling tube is arranged, so that the sampling tube does not obstruct the rotation of the arc-shaped material pushing plate 22 when the arc-shaped material pushing plate 22 rotates to adjust angles.

Specifically, the top surface of the material pressing disc 3 is of an inverted cone structure.

In this embodiment, since the top surface of the pressing tray 3 is of an inverted cone structure, the titanium dioxide falling on the top surface of the pressing tray 3 slides down to the center of the top surface of the pressing tray 3 due to gravity, that is, slides down to the gap between the pressing tray 3 and the driving shaft 71, so that the titanium dioxide can conveniently enter between the pressing tray 3 and the movable grinding disc 5 for subsequent grinding.

Specifically, the edge of the bottom surface of the material pressing disc 3 is provided with an inclined surface, and the inclined surface of the edge of the bottom surface of the material pressing disc 3 is parallel to the inclined surface of the push block 21.

In this embodiment, the bottom edge of the pressing tray 3 is provided with an inclined plane, the inclined plane of the bottom edge of the pressing tray 3 is parallel to the inclined plane of the pushing block 21, and the inclined planes of the bottom edge of the pressing tray 3 and the pushing block 21 are smooth inclined planes, so that the pushing block 21 presses the pressing tray 3 to push the pressing tray 3 to move upwards instead of Chang Shunhua.

Specifically, the top surface and the bottom surface of the movable millstone 5 are both provided with inclined planes, the bottom of the working cavity 13 is provided with a material blocking ring, and one side of the material blocking ring, which is close to the movable millstone 5, is provided with an inclined plane.

In this embodiment, because the top surface and the bottom surface of the movable millstone 5 are both provided with inclined surfaces, the bottom of the working cavity 13 is provided with a material blocking ring, and one side of the material blocking ring, which is close to the movable millstone 5, is provided with an inclined surface, so that titanium dioxide on the movable millstone 5 can conveniently fall into the grinding cavity 14, which is close to the edge of the movable millstone 5.

Specifically, the end of the connecting tube 263 extending out of the chassis 1 is provided with threads.

In this embodiment, the connection tube 263 extends out of the casing 1 to be conveniently screwed with the suction pump, so that a sample can be conveniently extracted.

Specifically, the grinding table 6 is a round table with a small top and a large bottom, and the inner diameter of the grinding cavity 14 is larger than the bottom diameter of the grinding table 6.

Specifically, a plurality of protrusions are arranged on the inner wall of the grinding cavity at equal intervals.

In this embodiment, since the grinding table 6 is a conical round table with a small top and a large bottom, the inner diameter of the grinding cavity 14 is larger than the diameter of the bottom of the grinding table, so that an annular space with a large top and a small bottom is formed between the grinding table 6 and the inner wall of the grinding cavity 14, a plurality of protrusions are equidistantly arranged on the inner wall of the grinding cavity 14, the driving motor 7 drives the grinding table 6 to rotate, and the grinding table 6 is matched with the annular space with a large top and a small bottom formed between the grinding table 6 and the inner wall of the grinding cavity 14, so that the grinding table 6 can squeeze, collide and crush titanium dioxide entering the grinding cavity 14 at a high speed, and finally the titanium dioxide falls into the aggregate cavity 15 after being crushed into uniform powder.

Working principle: solid titanium dioxide enters the dispersing cavity 12 from the feed hopper 11 and falls on the dispersing cover 4, the dispersing cover 4 is driven by the driving motor 7 to rotate, so that the fixed titanium dioxide is subjected to rebound scattering through the dispersing cover 4 and collides with the dispersing cover 4 and the inner wall of the dispersing cavity 12 to be primarily crushed, the solid titanium dioxide with larger volume is reduced, the subsequent crushing is facilitated, and the primarily crushed solid titanium dioxide falls on the top surface of the pressing tray 3;

because the top surface of the material pressing disc 3 is of an inverted cone structure, the titanium dioxide falling on the top surface of the material pressing disc 3 slides down to the center of the top surface of the material pressing disc 3 due to gravity, namely slides down to a gap between the material pressing disc 3 and the driving shaft 71, so that the titanium dioxide can conveniently enter between the material pressing disc 3 and the movable grinding disc 5;

because the pushing mechanism 2 is in sliding connection with the chassis 1, an operator pushes the pushing mechanism by hand or uses an electric push rod to push the pushing mechanism, so that the pushing mechanism 2 can displace in the horizontal direction, the pushing mechanism 2 displaces in the horizontal direction to drive the arc pushing plate 22 to enter between the pressing disc 3 and the movable millstone 5, and an inclined plane is arranged on one side of the pushing block 21, which is close to the pressing disc 3, so that the pushing mechanism 2 presses the pressing disc 3 to give an upward component force to the pressing disc 3 when driving the arc pushing plate 22 to enter between the pressing disc 3 and the movable millstone 5, a plurality of limit posts 31 are fixedly connected with the edge of the top surface of the pressing disc 3 at equal intervals, a limit hole is formed in the bottom of the dispersion cavity 12 corresponding to the limit post 31, a spring 32 is sleeved on the limit post 31, the bottom of the spring 32 is fixedly connected with the pressing disc 3, so that the spring 32 can compress, the limit post 31 displaces upwards in the limit hole, the gap between the pressing disc 3 and the movable millstone 5 is enlarged, and titanium dioxide between the pressing disc 3 and the movable millstone 5 is conveniently pushed by the arc pushing plate 22;

when the arc-shaped pushing plate 22 moves inwards along with the pushing mechanism 2 horizontally, the edge of the titanium dioxide driven millstone 5 between the material pressing disc 3 and the movable millstone 5 is pushed towards the center of the movable millstone 5, so that the titanium dioxide which just enters between the material pressing disc 3 and the movable millstone 5 and moves towards the edge of the movable millstone 5 due to extrusion is moved towards the center of the movable millstone 5 again to be piled up, the crushing effect is improved, the arc-shaped pushing plate 22 can push inwards again after retreating along with the pushing mechanism 2, and the titanium dioxide which enters between the material pressing disc 3 and the movable millstone 5 at different time can be mixed through the pushing process for a plurality of times, so that the crushing uniformity is improved;

the pushing mechanism 2 is circularly pushed inwards and outwards, so that the pushing mechanism 2 can be shifted in a reciprocating manner in the horizontal direction, the pushing block 21 on the pushing mechanism 2 can drive the pressing disc 3 to reciprocate up and down, and then the pressing disc 3 can generate periodic vibration, firstly, the arc pushing plate is matched to push the edge of the titanium dioxide driven disc 5 between the pressing disc 3 and the movable disc 5 to the center of the movable disc 5, so that the titanium dioxide which just enters between the pressing disc 3 and the movable disc 5 and moves to the edge of the movable disc 5 due to extrusion can be moved to the center of the movable disc 5 again to be piled up to be higher, the pressing disc 3 can periodically press the titanium dioxide between the pressing disc 3 and the movable disc 5, the crushing effect is improved, secondly, the periodic vibration can accelerate the titanium dioxide falling on the top surface of the pressing disc 3 to slide down to the center of the top surface of the pressing disc 3 due to gravity, namely slide to gaps between the pressing disc 3 and a driving shaft 71, and the titanium dioxide on the top surface of the pressing disc 3 can be accelerated to enter between the pressing disc 3 and the movable disc 5, and the excessive titanium dioxide piled up on the top surface of the pressing disc 3 is prevented;

the pushing mechanism 2 is in sliding connection with the chassis 1 through the matching of the sliding block 23 and the sliding groove, the control motor 24 can rotate positively and reversely, as the half gear 221 is fixedly connected to the arc pushing plate 22, the half gear 221 is rotationally connected with the pushing mechanism 2, one side of the upper half gear 221 of the pushing mechanism 2 away from the arc pushing plate 22 is rotationally connected with the driving gear 25, the driving gear 25 is meshed with the half gear 221, the bottom of the driving gear 25 is fixedly connected with the first driving wheel 251, the bottom of the rotating shaft of the control motor 24 is fixedly connected with the second driving wheel 242, the first driving wheel 251 is connected with the second driving wheel 242 through a driving chain, the control motor 24 can drive the driving gear 25 to rotate through the driving chain belt, so that the half gear 221 is driven to rotate, and the arc pushing plate 22 can rotate to adjust the angle;

when the arc-shaped material pushing plate 22 enters between the material pressing disc 3 and the movable millstone 5, the movable millstone 5 continuously rotates, the arc-shaped material pushing plate 22 is attached to the top surface of the movable millstone 5, a slope is arranged at the bottom of the arc-shaped material pushing plate 22, so that the arc-shaped material pushing plate 22 scrapes titanium dioxide powder adhered to the surface of the movable millstone 5, and then the arc-shaped material pushing plate 22 is matched for rotatably adjusting an angle, so that the arc-shaped material pushing plate 22 can be contacted with the movable millstone 5 from the axis to the edge, namely, the arc-shaped material pushing plate 22 can scrape all titanium dioxide adhered everywhere on the surface of the movable millstone 5, and the more powder is prevented from being accumulated;

simultaneously, the arc-shaped pushing plate 22 can push scraped titanium dioxide to the edge of the movable millstone 5 through adjusting the angle, and as the top surface and the bottom surface of the movable millstone 5 are both provided with inclined planes, the bottom of the working cavity 13 is provided with a material blocking ring, and one side of the material blocking ring, which is close to the movable millstone 5, is provided with an inclined plane, so that the titanium dioxide on the movable millstone 5, which is close to the edge of the movable millstone 5, can conveniently fall into the grinding cavity 14;

when the sampling head 26 enters between the material pressing disc 3 and the movable millstone 5 along with the arc material pushing plate 22, the arc material pushing plate 22 starts to push materials, titanium dioxide pushed by the arc material pushing plate 22 is piled up in front of the arc material pushing plate 22, so that the sampling head 26 is inserted into the piled titanium dioxide, the sampling head 26 is convenient to extract samples through a sampling tube, and as the arc material pushing plate 22 can rotate an adjusting angle, the sampling head 26 can reach each position from the axis of the movable millstone 5 to the edge when the arc material pushing plate 22 rotates the adjusting angle, the sampling head 26 is convenient to extract samples at different positions, and the telescopic hose 262 in the sampling tube is arranged, so that the sampling tube does not prevent the rotation of the arc material pushing plate 22 when the arc material pushing plate 22 rotates the adjusting angle;

one end of the connecting pipe 263, which extends out of the case 1, can be conveniently connected with a suction pump through threads, so that a sample can be conveniently extracted;

because the grinding table 6 is a conical round table with a small top and a large bottom, the inner diameter of the grinding cavity 14 is larger than the diameter of the bottom of the grinding table, so that an annular space with a large top and a small bottom is formed between the grinding table 6 and the inner wall of the grinding cavity 14, the inner wall of the grinding cavity 14 can be provided with grinding protrusions, the driving motor 7 drives the grinding table 6 to rotate, the grinding table 6 is matched with the annular space with the large top and the small bottom formed between the grinding table 6 and the inner wall of the grinding cavity 14, titanium dioxide entering the grinding cavity 14 can be extruded and crashed at a high speed, and finally the titanium dioxide falls into the aggregate cavity 15 after being crashed into uniform powder, and finally is discharged out of the machine case 1 through the discharge hole.

The foregoing is only a preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be able to apply equivalents and modifications according to the technical scheme and the modified concept of the present invention within the scope of the present invention.

Claims (9)

1. The utility model provides a titanium dioxide production crushing apparatus, includes quick-witted case (1), pushing equipment (2), presses charging tray (3), dispersion cover (4), moves mill (5), grinding table (6), driving motor (7), its characterized in that: the novel grinding machine is characterized in that the driving motor (7) is fixedly connected to the bottom of the machine case (1), a feed hopper (11) is fixedly arranged at the top of the machine case (1), a discharge hole is formed in the bottom of the machine case (1), a driving shaft (71) is fixedly connected to a rotating shaft of the driving motor (7), a dispersing cover (4), a movable grinding disc (5) and a grinding table (6) are sequentially and fixedly connected to the driving shaft (71) from top to bottom, the material pressing disc (3) is arranged between the dispersing cover (4) and the movable grinding disc (5), the driving shaft (71) penetrates through the material pressing disc (3), a gap is formed between the material pressing disc (3) and the driving shaft (71), and the material pushing mechanism (2) is arranged on one side of the material pressing disc (3) and one side of the movable grinding disc (5).

The novel material pushing device is characterized in that a dispersing cavity (12) is arranged below a feeding hopper (11) on the chassis (1), a plurality of limiting columns (31) are fixedly connected to the edge of the top surface of the material pushing disc (3) at equal intervals, limiting holes are formed in the positions, corresponding to the limiting columns (31), of the bottom of the dispersing cavity (12), springs (32) are sleeved on the limiting columns (31), the bottoms of the springs (32) are fixedly connected with the material pushing disc (3), the tops of the springs (32) are fixedly connected with the bottoms of the dispersing cavities (12), the material pushing mechanisms (2) are in sliding connection with the chassis (1), arc-shaped material pushing plates (22) are rotatably connected to one ends, extending into the chassis (1), of the material pushing mechanisms (2), and pushing blocks (21) are fixedly connected to the upper portions of the arc-shaped material pushing plates (22);

the novel automatic feeding device is characterized in that a first limiting plate (231) is fixedly connected to the pushing mechanism (2) in the chassis (1), a second limiting plate (232) is fixedly connected to the pushing mechanism (2) in the chassis (1), a sliding block (23) is arranged between the first limiting plate (231) and the second limiting plate (232), a sliding groove is formed in the chassis (1) corresponding to the sliding block (23), the sliding block (23) is in sliding connection with the sliding groove, a half gear (221) is fixedly connected to the arc pushing plate (22), the half gear (221) is rotationally connected with the pushing mechanism (2), a driving gear (25) is rotationally connected to one side, away from the arc pushing plate (22), of the pushing mechanism (2), the driving gear (25) is meshed with the half gear (221), a first motor (251) is fixedly connected to the bottom of the driving gear (25), a seat (241) is fixedly connected to the outer side of the second limiting plate (232), a control motor (24) is fixedly connected to the motor seat (241), and a control motor (24) is fixedly connected with a second driving wheel (242) through a driving wheel (242).

2. The titanium dioxide production crushing apparatus according to claim 1, wherein: the utility model discloses a grinding machine, including dispersing chamber (12), grinding chamber (14) below is provided with chamber (15) gathers materials, chamber (15) bottom is provided with the discharge gate gathers materials, quick-witted case (1) bottom fixedly connected with support column (16), fixedly connected with fixed disk (72) on driving motor (7), fixed disk (72) and support column (16) fixed connection, dispersing cover (4) set up under feeder hopper (11) in dispersing chamber (12), pushing equipment (2), swager dish (3), movable millstone (5) set up in working chamber (13), grinding table (6) set up in grinding chamber (14).

3. A titanium dioxide production crushing plant according to claim 2, characterized in that: the utility model discloses a sampling tube, including arc-shaped pushing plate (22), arc-shaped pushing plate (22) is gone up inboard both ends fixedly connected with sampling head (26), sampling head (26) and sampling tube intercommunication, the sampling tube includes arc-shaped tube (261), flexible hose (262) and connecting pipe (263), arc-shaped tube (261) fixed connection is in arc-shaped pushing plate (22) outside, connecting pipe (263) run through first limiting plate (231), slider (23), second limiting plate (232) stretch out outside quick-witted case (1), flexible hose (262) one end and arc-shaped tube (261) intercommunication, flexible hose (262) other end and connecting pipe (263) intercommunication.

4. The titanium dioxide production crushing apparatus according to claim 1, wherein: the top surface of the material pressing disc (3) is of an inverted cone structure.

5. The titanium dioxide production crushing apparatus according to claim 1, wherein: the edge of the bottom surface of the material pressing disc (3) is provided with an inclined surface, and the inclined surface of the edge of the bottom surface of the material pressing disc (3) is parallel to the inclined surface of the pushing block (21).

6. A titanium dioxide production crushing plant according to claim 3, characterized in that: the top surface and the bottom surface of the movable millstone (5) are respectively provided with an inclined surface, the bottom of the working cavity (13) is provided with a material blocking ring, and one side of the material blocking ring, which is close to the movable millstone (5), is provided with an inclined surface.

7. A titanium dioxide production crushing plant according to claim 3, characterized in that: the connecting pipe (263) extends out of the case (1) and is provided with threads at one end.

8. A titanium dioxide production crushing plant according to claim 3, characterized in that: the grinding table (6) is a round table with a small top and a large bottom, and the inner diameter of the grinding cavity (14) is larger than the bottom diameter of the grinding table (6).

9. A titanium dioxide production crushing plant according to claim 3, characterized in that: a plurality of bulges are equidistantly arranged on the inner wall of the grinding cavity (14).