CN221619985U - Ore sieving mechanism for metal smelting - Google Patents

Abstract

The utility model relates to the field of ore processing, and in particular to an ore screening device for metal smelting. The utility model enables the filter screen to slide back and forth horizontally, thereby preventing the filter screen from being stuck by ores of different sizes, thereby improving the screening efficiency of ores of different sizes. The utility model includes a base and a support seat, etc.; the support seat is fixedly connected to the middle of the upper side of the base. The ore falls on the conveyor belt, and the motor drives the conveyor belt and the ore to rotate obliquely downward. The filter screen performs preliminary screening of the ore, so that the larger ore is blocked on the side of the filter screen close to the feed hopper, and the smaller ore passes through the filter screen and falls along the conveyor belt to the side of the base away from the feed hopper. Then the motor drives the larger ore blocked on one side of the filter screen to move obliquely upward, and the larger ore falls on the discharge box, so that the filter screen performs preliminary screening of ores of different sizes, thereby classifying and collecting ores of different sizes, thereby improving the screening efficiency of the ore.

Description

Ore screening device for metal smelting

Technical Field

The utility model relates to the field of ore processing, in particular to an ore screening device for metal smelting.

Background Art

Ore is a stone containing some valuable minerals mined from a mine. After being crushed and processed, the ore can be used in multiple industries and other engineering fields. The newly produced ore must be crushed first, and then transported to various processing sites according to the size of the ore fragments to meet the final operation of different particle sizes of the ore. Most of the existing ore screening is to screen ores of different sizes through a screen. Due to the different sizes of the ore, the screen is easily stuck by the ore, and the screening efficiency is low.

Utility Model Content

In view of the shortcomings or deficiencies of the above-mentioned prior art, the utility model provides an ore screening device for metal smelting, which can make the filter screen slide back and forth horizontally, thereby preventing the filter screen from being stuck by ores of different sizes, thereby improving the screening efficiency of ores of different sizes.

A device for screening ore for metal smelting comprises a base, a support base, a feed hopper, a discharge box, a baffle, a bracket, a conveyor belt, a rotating shaft, a motor and a filter screen. The support base is fixedly connected to the middle part of the upper side surface of the base, the feed hopper is fixedly connected to the top of one end of the base close to the support base, a discharge box is placed on the upper side surface of the base close to the feed hopper, the baffle is fixedly connected to the top of the support base, the baffle is inclined, the discharge port of the feed hopper is fixedly connected to the top of one end of the baffle close to the discharge box, the bracket is fixedly connected to the middle part of the support base, the middle part of the bracket is in contact with the middle part of the baffle, two rotating shafts are rotatably connected to the upper part of the support base, one of the rotating shafts is fixedly connected to the output shaft of the motor, a conveyor belt is wound between the two rotating shafts, both sides of the conveyor belt are in contact with the baffle, the middle part of the bracket is slidably connected to the filter screen, and the filter screen passes through the baffle.

Further description, it also includes protrusions and shaking frames. Several protrusions are fixedly connected on both sides of the conveyor belt. The protrusions on both sides of the conveyor belt are staggered. Shaking frames are fixedly connected on both sides of the filter screen. Cylinders are provided at the bottom of the two shaking frames. Several protrusions on both sides of the conveyor belt will contact the cylinders on the two shaking frames in turn.

Further description, it also includes a filter box and a dust box. The dust box is clamped on the upper side of the base away from the feed hopper, and the filter box is placed on the top of the dust box. The filter box is clamped on the base, and a plurality of filter holes are opened at the bottom of the filter box. One side of the filter box is in contact with the end of the conveyor belt away from the feed hopper.

Further description: the bracket is arranged vertically.

The beneficial effects of the utility model are as follows: when the ore is placed in the feed hopper, the ore will fall onto the conveyor belt, and then the motor drives the conveyor belt to rotate obliquely downward through the output shaft, and the conveyor belt drives the ore to rotate obliquely downward, and the filter screen performs preliminary screening on the ore, so that the larger ore is blocked on the side of the filter screen close to the feed hopper, and the smaller ore can pass through the filter screen and fall along the conveyor belt to the side of the base away from the feed hopper, then the operator adjusts the motor to rotate in the opposite direction, and the motor drives the larger ore blocked on one side of the filter screen to move obliquely upward, and the larger ore falls onto the discharge box, so that the filter screen performs preliminary screening on ores of different sizes, thereby classifying and collecting ores of different sizes, thereby improving the screening efficiency of the ore.

One of the protrusions lifts one of the shaking frames, and one of the shaking frames drives the other shaking frame and the filter to slide horizontally. The conveyor belt continues to drive several protrusions to rotate. The cylinder on one of the shaking frames disengages from one of the protrusions on one side, and at the same time, the cylinder on the other shaking frame contacts another protrusion on the other side. The other protrusion drives the two shaking frames and the filter to slide horizontally in the opposite direction, and so on and so forth, so that the two shaking frames drive the filter to slide horizontally back and forth, preventing the filter from being stuck by the ore, thereby further improving the screening efficiency of the ore.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG1 is a schematic diagram of a first three-dimensional structure of the utility model.

FIG. 2 is a schematic diagram of a second three-dimensional structure of the present invention.

FIG. 3 is a schematic diagram of a third three-dimensional structure of the present invention.

FIG. 4 is an enlarged three-dimensional structural schematic diagram of A in FIG. 3 of the present invention.

Markings in the attached drawings: 1: base, 2: support base, 3: feed hopper, 4: discharge box, 5: baffle, 6: bracket, 7: conveyor belt, 8: rotating shaft, 9: motor, 10: filter screen, 11: protrusion, 12: shaking frame, 13: filter box, 14: dust box.

DETAILED DESCRIPTION

The following will be combined with the drawings in the embodiments of the utility model to clearly and completely describe the technical solutions in the embodiments of the utility model. Obviously, the described embodiments are only part of the embodiments of the utility model, not all of the embodiments. Based on the embodiments of the utility model, all other embodiments obtained by ordinary technicians in this field without creative work are within the scope of protection of the utility model.

Embodiment 1: An ore screening device for metal smelting, as shown in Figures 1 to 3, includes a base 1, a support base 2, a feed hopper 3, a discharge box 4, a baffle 5, a bracket 6, a conveyor belt 7, a rotating shaft 8, a motor 9 and a filter screen 10. The support base 2 is welded to the middle of the upper side of the base 1, and the top of the end of the base 1 close to the support base 2 is connected to the feed hopper 3 by bolts. The discharge box 4 is placed on the end of the upper side of the base 1 close to the feed hopper 3. The baffle 5 is welded to the top of the support base 2, and the baffle 5 is inclined. The discharge port of the feed hopper 3 is connected to the top of one end of the baffle 5 close to the discharge box 4 by bolts, a bracket 6 is welded to the middle of the support seat 2, the middle of the bracket 6 is in contact with the middle of the baffle 5, the bracket 6 is vertically arranged, and two rotating shafts 8 are rotatably connected to the upper part of the support seat 2, one of the rotating shafts 8 is welded to the output shaft of the motor 9, a conveyor belt 7 is wound between the two rotating shafts 8, both sides of the conveyor belt 7 are in contact with the baffle 5, and a filter screen 10 is slidably connected to the middle of the bracket 6, and the filter screen 10 passes through the baffle 5.

First, the operator places the ore in the feed hopper 3, and the ore falls on the conveyor belt 7. Then the operator starts the motor 9, and the motor 9 drives one of the rotating shafts 8 to rotate through the output shaft. One of the rotating shafts 8 drives the other rotating shaft 8 to rotate through the conveyor belt 7, so that the conveyor belt 7 rotates obliquely downward, and the conveyor belt 7 drives the ore to move obliquely downward. The ore contacts the filter screen 10, and the conveyor belt 7 continues to rotate obliquely downward, so that the filter screen 10 performs a preliminary screening of the ore, so that larger ores are blocked on the side of the filter screen 10 close to the feed hopper 3, and smaller ores can pass through the filter screen 10 and fall along the conveyor belt 7 to the base 1 away from the feed hopper. 3, and then the operator adjusts the motor 9 to make the motor 9 rotate in the opposite direction. The motor 9 drives the two rotating shafts 8 and the conveyor belt 7 to rotate in the opposite direction through the output shaft. The conveyor belt 7 drives the larger ore blocked on one side of the filter screen 10 to move obliquely upward, and the larger ore is separated from the conveyor belt 7, and the larger ore falls on the discharge box 4, so that the filter screen 10 performs preliminary screening of ores of different sizes, thereby classifying and collecting ores of different sizes, thereby improving the screening efficiency of the ore. When the ore is screened, the operator turns off the motor 9, and the output shaft of the motor 9 no longer drives the conveyor belt 7 to rotate, and the operator takes out the ore in the discharge box 4.

Embodiment 2: Based on Embodiment 1, as shown in FIG. 3-4, it further includes protrusions 11 and shaking frames 12. A plurality of protrusions 11 are welded on both sides of the conveyor belt 7. The protrusions 11 on both sides of the conveyor belt 7 are staggered. The shaking frames 12 are connected to both sides of the filter screen 10 by rivets. Cylinders are provided at the bottom of the two shaking frames 12. The plurality of protrusions 11 on both sides of the conveyor belt 7 will contact the cylinders on the two shaking frames 12 in turn.

When the conveyor belt 7 rotates, the conveyor belt 7 drives several protrusions 11 on both sides to rotate. When the cylinder on one of the shaking frames 12 contacts one of the protrusions 11 on one side, one of the protrusions 11 lifts one of the shaking frames 12. One of the shaking frames 12 is limited by the bracket 6. One of the shaking frames 12 drives the other shaking frame 12 and the filter screen 10 to slide horizontally. The conveyor belt 7 continues to rotate, and the cylinder on one of the shaking frames 12 disengages from one of the protrusions 11 on one side. At the same time, the cylinder on the other shaking frame 12 contacts another protrusion 11 on the other side. Another protrusion 11 lifts another shaking frame 12. Another protrusion 11 drives the two shaking frames 12 and the filter screen 10 to slide horizontally in the opposite direction. This reciprocating process makes the two shaking frames 12 drive the filter screen 10 to slide horizontally back and forth, thereby preventing the filter screen 10 from being stuck by the ore, thereby improving the screening efficiency of the ore.

Embodiment 3: Based on Embodiment 2, as shown in FIG2 , a filter box 13 and a dust box 14 are further included. The dust box 14 is clamped on the upper side of the end of the base 1 away from the feed hopper 3. The filter box 13 is placed on the top of the dust box 14. The filter box 13 is clamped on the base 1. A plurality of filter holes are opened at the bottom of the filter box 13. One side of the filter box 13 is in contact with the end of the conveyor belt 7 away from the feed hopper 3.

When larger ores are blocked by the filter screen 10 on the side close to the feed hopper 3, smaller ores continue to move obliquely downward along the conveyor belt 7 through the filter screen 10, and the conveyor belt 7 transports the smaller ores to the filter box 13. The smaller ores will be retained in the upper layer by the filter box 13, while other powders or debris will pass through the filter box 13 and fall into the dust box 14 at the bottom, thereby conveniently and quickly screening ores of different sizes, further improving the screening efficiency of the ores. After the ore is screened, the operator takes out the ore in the filter box 13.

Although the embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that various changes, modifications, substitutions and variations may be made to the embodiments without departing from the principles and spirit of the present invention, and that the scope of the present invention is defined by the appended claims and their equivalents.

Claims (4)

1. An ore screening device for metal smelting, characterized in that it comprises a base (1), a support base (2), a feed hopper (3), a discharge box (4), a baffle (5), a bracket (6), a conveyor belt (7), a rotating shaft (8), a motor (9) and a filter screen (10), wherein the middle part of the upper side of the base (1) is fixedly connected to the support base (2), the top of the end of the base (1) close to the support base (2) is fixedly connected to the feed hopper (3), the end of the upper side of the base (1) close to the feed hopper (3) is placed with the discharge box (4), the top of the support base (2) is fixedly connected to the baffle (5), and the baffle (5) The feeding hopper (3) is arranged in an inclined manner, the discharge port of the feeding hopper (3) is fixedly connected to the top of one end of the baffle (5) close to the discharge box (4), the middle of the support seat (2) is fixedly connected to a bracket (6), the middle of the bracket (6) is in contact with the middle of the baffle (5), the upper part of the support seat (2) is rotatably connected to two rotating shafts (8), one of the rotating shafts (8) is fixedly connected to the output shaft of the motor (9), a conveyor belt (7) is wound between the two rotating shafts (8), both sides of the conveyor belt (7) are in contact with the baffle (5), and a filter screen (10) is slidably connected to the middle of the bracket (6), and the filter screen (10) passes through the baffle (5). 2. An ore screening device for metal smelting according to claim 1, characterized in that: it also includes protrusions (11) and shaking frames (12), a plurality of protrusions (11) are fixedly connected to both sides of the conveyor belt (7), the protrusions (11) on both sides of the conveyor belt (7) are staggered, and a shaking frame (12) is fixedly connected to both sides of the filter net (10), and cylinders are provided at the bottom of the two shaking frames (12), and the plurality of protrusions (11) on both sides of the conveyor belt (7) will contact the cylinders on the two shaking frames (12) in turn. 3. An ore screening device for metal smelting according to claim 2, characterized in that it also includes a filter box (13) and a dust box (14), the dust box (14) is clamped on the upper side of the end of the base (1) away from the feed hopper (3), and the filter box (13) is placed on the top of the dust box (14), the filter box (13) is clamped with the base (1), and a plurality of filter holes are opened at the bottom of the filter box (13), and one side of the filter box (13) is in contact with the end of the conveyor belt (7) away from the feed hopper (3). 4. An ore screening device for metal smelting according to claim 1, characterized in that the bracket (6) is arranged vertically.