CN217094472U - Tin ore coarse fodder iron sieving mechanism - Google Patents

Abstract

The utility model discloses a tin ore coarse fodder iron sieving mechanism, include: the top of the screening box is provided with a first filter plate which is obliquely arranged, and a second filter plate and a third filter plate which are obliquely arranged towards the two sides of the screening box are respectively arranged in the screening box from bottom to top; the spray head is arranged on the outer wall of the screening box; the first collecting box is arranged at the bottom of the first filter plate and used for receiving the raw materials screened from the first filter plate; the second collecting box is arranged at the bottom of the second filter plate and is used for receiving the raw materials screened from the second filter plate; the third collecting box is arranged at the bottom of the first filter plate and used for receiving the raw materials screened from the third filter plate; and the magnetic suction roller is used for screening out ferromagnetic sundries in the raw materials. Has the advantages that: adopt the structural design of multilayer filter plate cooperation magnetic suction roller, can continuously divide the sieve to ore raw materials, the treatment effeciency is high, can realize the granularity simultaneously and divide the sieve and collect, the follow-up processing of being convenient for, the practicality is strong.

Description

Tin ore coarse fodder iron sieving mechanism

Technical Field

The utility model relates to a mineral processing equipment technical field, concretely relates to tin ore coarse fodder iron sieving mechanism.

Background

In the ore dressing process of tin ore, need generally to separate common miscellaneous ore from the ore dressing material, thereby promote the purity of ore, so that follow-up carry out the finish machining, adopt the ferromagnetism to divide the sieve usually, but the major problem that current branch sieve equipment exists in the course of working lies in, precision when dividing the sieve is limited, only filter the ore material, can't divide the granularity of sieve ore, and simultaneously, the efficiency of dividing the sieve is not enough, the handling capacity is less, can not satisfy the user demand in present stage, and the practicality is relatively poor.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a tin ore coarse fodder iron sieving mechanism just in order to solve above-mentioned problem to the precision when solving among the prior art target mineral and screening is limited, only filters the ore material, can't divide the granularity of screening the ore, and simultaneously, the efficiency of dividing the sieve is not enough, and the handling capacity is less, can not satisfy the user demand in present stage, the relatively poor technical problem of practicality. The utility model provides an adopt the structural design of multilayer filter plate cooperation magnetism suction roller among the preferred technical scheme among a great deal of technical scheme, can continuously divide the sieve to ore raw materials, the treatment effeciency is high, can realize the granularity simultaneously and divide the sieve and collect, the follow-up processing of being convenient for, the technological effect that the practicality is strong sees the explanation below in detail.

In order to achieve the above purpose, the utility model provides a following technical scheme:

the utility model provides a tin ore coarse fodder iron sieving mechanism, include:

the top of the screening box is provided with a first filter plate which is obliquely arranged, and a second filter plate and a third filter plate which are obliquely arranged towards the two sides of the screening box are respectively arranged in the screening box from bottom to top;

the spray head is arranged on the outer wall of the screening box and used for pushing the ore to move on the filter plate;

the first collecting box is arranged at the bottom of the first filter plate and used for receiving the raw materials screened from the first filter plate;

the second collecting box is arranged at the bottom of the second filter plate and is used for receiving the raw materials screened from the second filter plate;

the third collecting box is arranged at the bottom of the first filter plate and used for receiving the raw materials screened from the third filter plate;

the magnetic suction rollers are arranged in the second collecting box and the third collecting box and are used for screening out ferromagnetic sundries in the raw materials;

and the main driving motor and the auxiliary driving motor are respectively arranged on the outer walls of the third collecting box and the second collecting box and are used for driving the magnetic suction roller to rotate.

Preferably, the inner wall of the screen separating box is provided with a bearing seat for mounting the first filter plate and the second filter plate, and the bearing seat is provided with a vibrating motor for driving the first filter plate and the second filter plate to vibrate up and down.

Preferably, the inner walls of the first collecting box and the second collecting box are provided with guide plates.

Preferably, the top of the screening box is provided with baffle plates which are symmetrically arranged on two sides.

Preferably, the inner walls of the second collecting box and the third collecting box are provided with impurity boxes for collecting the screened ferromagnetic materials.

Preferably, a scraper attached to the magnetic suction roller is arranged on the impurity box.

Has the advantages that:

1. adopt the structural design of multilayer filter plate cooperation magnetic suction roller, can continuously divide the sieve to ore raw materials, the treatment effeciency is high, can realize the granularity simultaneously and divide the sieve and collect, the follow-up processing of being convenient for, the practicality is strong.

2. The first filter plate and the second filter plate are driven to vibrate through the matching of the bearing seat and the vibration motor, so that the moving efficiency of the ore raw materials on the first filter plate and the second filter plate can be improved, and material accumulation is avoided;

3. the ore raw materials conveyed from the filter plate can be guided through the guide plate, so that the ore is in contact with the magnetic suction roller after being guided out, the ore raw materials can be ensured to be in contact with the magnetic suction roller in the conveying process, and the screening effect is ensured;

4. by adopting the structural design of the baffle, the top edge of the sieving box can be protected and limited, so that ores can be prevented from sliding off from two sides of the sieving box in the conveying process of the baffle, all the ores can be conveyed by the first filtering plate, and the precision in filtering is ensured;

5. through the design of the impurity box, ferromagnetic impurities filtered by the magnetic suction roller can be collected and stored, so that the ferromagnetic impurities can be conveniently separated, stored and processed at the later stage;

6. scrape through the scraper blade and get to send into the miscellaneous incasement of miscellaneous material and collect, can separate with the purpose mineral, and save respectively, so that follow-up collection.

Drawings

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

Fig. 1 is a first perspective view of the present invention;

fig. 2 is a top view of the present invention;

fig. 3 is a second perspective view of the present invention;

fig. 4 is a front view of the present invention;

FIG. 5 is a view of the structure of FIG. 4 from direction A-A;

fig. 6 is an enlarged view of a portion of fig. 5 according to the present invention;

fig. 7 is a right side view of the present invention.

The reference numerals are explained below:

1. a guide plate; 2. a squeegee; 3. a magnetic suction roller; 4. a second filter plate; 5. a first collection tank; 6. a baffle plate; 7. a first filter plate; 8. a spray head; 9. a main drive motor; 10. a third collection tank; 11. a screening box; 12. a secondary drive motor; 13. a second collection tank; 14. a sundry box; 15. a third filter plate; 16. a vibration motor; 17. a bearing seat.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention clearer, the technical solutions of the present invention will be described in detail below. It is to be understood that the embodiments described are only some embodiments of the invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative efforts belong to the protection scope of the present invention.

Referring to fig. 1-7, the utility model provides a tin ore coarse fodder iron sieving mechanism, include:

the screening box 11 is a cuboid structure with two hollow sides, so that filter plates can be installed, a first filter plate 7 which is obliquely arranged is arranged at the top of the screening box 11, the first filter plate 7 is obliquely arranged along the length direction, raw materials placed on the first filter plate 7 can move along the first filter plate 7, the oversize raw materials are screened out and collected through sieve pores on the surface of the filter plates, the raw materials are crushed again, a second filter plate 4 and a third filter plate 15 which are obliquely arranged towards the two sides of the screening box 11 are respectively arranged inside the screening box 11 from bottom to top, two ends of the second filter plate 4 and the third filter plate 15 are respectively abutted against the inner wall of the screening box 11, the sieve pores on the first filter plate 7, the second filter plate 4 and the third filter plate 15 are reduced step by step, so that the ore raw materials can be screened step by step, when the screening box is used, the materials fall on the obliquely arranged second filter plate 4 after being screened by the first filter plate 7, the materials can be guided to the third filter plate 15 after being subjected to screening treatment by the second filter plate 4, and the raw materials are respectively screened and collected step by step;

the spray heads 8 are arranged on the outer wall of the screening box 11 and used for pushing the ores to move on the filter plate, the spray heads 8 are seven and are arranged at equal intervals, the spray heads 8 can spray and guide materials on the spray heads 8, the end parts of the spray heads 8 are connected with an external water pump through pipelines, and the water outlet ends of the spray heads 8 are flat strip holes, so that the water outlet amount can be increased, and the ore transmission efficiency is improved;

the first collecting box 5 is arranged at the bottom of the first filtering plate 7 and used for receiving the raw materials screened from the first filtering plate 7 and collecting the ore raw materials with the largest size;

the second collecting box 13 is arranged at the bottom of the second filter plate 4 and is used for receiving the raw materials screened from the second filter plate 4 and collecting ore raw materials with larger sizes;

the third collecting box 10 is arranged at the bottom of the first filtering plate and used for receiving the raw materials screened from the third filtering plate 15 and collecting the ore fuel with smaller size;

the magnetic suction rollers 3 are arranged in the second collecting box 13 and the third collecting box 10 and used for screening out ferromagnetic sundries in raw materials, and the magnetic suction rollers 3 are horizontally arranged and can be used for adsorbing and collecting ore raw materials led into the second collecting box 13 and the third collecting box 10, so that the ferromagnetic sundries can be screened out, and the purity of tin ore is improved;

the main driving motor 9 and the auxiliary driving motor 12 are respectively arranged on the outer walls of the third collecting box 10 and the second collecting box 13 and are used for driving the magnetic suction roller 3 to rotate, and the magnetic suction roller 3 can be driven to rotate through continuous rotation of the magnetic suction roller 3, so that the screening efficiency of the ore raw materials is improved;

when the ore material separating device is used, an operator connects an external water pipe with the water pump and the spray head 8 so as to supply water to the spray head 8, when ore material is thrown into the separating box 11 from the top, water flow drives the ore material to continuously move along the first filter plate 7, and gradually separates oversized ore through sieve pores formed in the surface of the first filter plate 7, the separated ore can continuously move along the first filter plate 7 and finally fall into the first collecting box 5 for storage, the ore meeting the size requirement can pass through the first filter plate 7 to fall on the third filter plate 15 and continuously move along the third filter plate 15, in the process, the main driving motor 9 works to drive the magnetic suction roller 3 in the third collecting box 10 to rotate, so that the material can be contacted with the magnetic suction roller 3 when being led out from the third filter plate 15, and ferromagnetic miscellaneous ores in the material can be led out, similarly, the ore material screened by the third filter 15 falls on the second filter 4 under the action of gravity, and moves and screens along the second filter 4, and finally the target ore with the smallest particle size is screened into the bottom space of the screening box 11, and the target ore with the secondary size is screened to the bottoms of the second collection box 13 and the third collection box 10 respectively, so that particle size screening and classified storage are realized.

In another embodiment, a supporting seat 17 for mounting the first filter plate 7 and the second filter plate 4 is arranged on the inner wall of the screening box 11, a vibration motor 16 for driving the first filter plate 7 and the second filter plate 4 to vibrate up and down is arranged on the supporting seat 17, the first filter plate 7 and the second filter plate 4 are hinged on the inner wall of the screening box 11 through a rotating shaft, the first filter plate 7 and the second filter plate 4 can be driven to vibrate along the rotating shaft through the vibration motor 16, so that the efficiency of moving the ore raw material on the first filter plate 7 and the second filter plate 4 is accelerated, and material accumulation is avoided.

In another embodiment, the guide plates 1 are arranged on the inner walls of the first collecting box 5 and the second collecting box 13, two ends of each guide plate 1 are respectively close to the first filter plate 7 and the magnetic suction roller 3, and the ore raw materials conveyed from the second filter plate 4 or the first filter plate 7 can be guided, so that the ore is in contact with the magnetic suction roller 3 after being guided out, and further the ore raw materials can be ensured to be in contact with the magnetic suction roller 3 in the conveying process, and the screening effect is ensured.

In another embodiment, the top of the screening box 11 is provided with the baffle 6 which is symmetrically arranged on two sides, and the structural design of the baffle 6 is adopted, so that the top edge of the screening box 11 can be protected and limited, further, the baffle 6 is prevented from sliding off from two sides of the screening box 11 in the conveying process, all ores can be conveyed through the first filtering plate 7, and the filtering precision is ensured.

In another embodiment, the inner walls of the second collection box 13 and the third collection box 10 are both provided with a impurity box 14 for collecting the screened ferromagnetic materials, and the ferromagnetic materials filtered out by the magnetic suction roller 3 can be collected and stored by the design of the impurity box 14, so that the ferromagnetic materials can be conveniently separated, stored and processed in the later period.

In another embodiment, be equipped with the scraper blade 2 that pastes tight magnetism suction roll 3 on miscellaneous workbin 14, magnetism suction roll 3 is hugged closely on the top of scraper blade 2, and for the arc structure of adaptation magnetism suction roll 3 outer wall, adopts the structural design of scraper blade 2, can inhale the ferromagnetism miscellaneous material of roller 3 adhesion when rotatory with the magnetism, scrapes through scraper blade 2 and gets to send into miscellaneous workbin 14 and collect, can with the separation of purpose mineral, and save respectively, so that follow-up collection.

The above embodiments are only specific embodiments of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art can easily think of changes or substitutions within the technical scope of the present invention, and all should be covered within the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims (6)

1. The utility model provides a tin ore coarse fodder iron sieving mechanism which characterized by: the method comprises the following steps:

the screen separating box (11), the top of the screen separating box (11) is provided with a first filter plate (7) which is obliquely arranged, and the inside of the screen separating box (11) is respectively provided with a second filter plate (4) and a third filter plate (15) which are obliquely arranged towards two sides of the screen separating box (11) from bottom to top;

the spray head (8) is arranged on the outer wall of the screening box (11) and is used for pushing the ore to move on the filter plate;

the first collecting box (5) is arranged at the bottom of the first filtering plate (7) and is used for receiving the raw materials screened from the first filtering plate (7);

the second collecting box (13) is arranged at the bottom of the second filter plate (4) and is used for receiving the raw materials screened from the second filter plate (4);

the third collecting box (10) is arranged at the bottom of the first filtering plate and is used for receiving the raw materials screened from the third filtering plate (15);

the magnetic suction roller (3) is arranged in the second collecting box (13) and the third collecting box (10) and is used for screening out ferromagnetic sundries in the raw materials;

and the main driving motor (9) and the auxiliary driving motor (12) are respectively arranged on the outer walls of the third collecting box (10) and the second collecting box (13) and are used for driving the magnetic suction roller (3) to rotate.

2. The tin ore coarse iron screening apparatus according to claim 1, characterized in that: be equipped with bearing seat (17) that are used for installing first filter (7) and second filter (4) on the inner wall of branch sieve case (11), be equipped with vibrating motor (16) that drive first filter (7) and second filter (4) vibration from top to bottom on bearing seat (17).

3. The tin ore coarse iron screening device of claim 1, characterized in that: and guide plates (1) are arranged on the inner walls of the first collecting box (5) and the second collecting box (13).

4. The tin ore coarse iron screening apparatus according to claim 1, characterized in that: the top of the screening box (11) is provided with baffle plates (6) which are symmetrically arranged at two sides.

5. The tin ore coarse iron screening apparatus according to claim 1, characterized in that: and impurity boxes (14) are arranged on the inner walls of the second collecting box (13) and the third collecting box (10) and used for collecting screened ferromagnetic materials.

6. The tin ore coarse iron screening device of claim 5, characterized in that: the impurity box (14) is provided with a scraper (2) which is tightly attached to the magnetic suction roller (3).

Images