CN215278419U - Zinc ingot classifying and screening device for industrial solid waste processing - Google Patents

Abstract

The utility model discloses an industry solid waste processing is with zinc spindle grading screening plant, including device body, air pump, spacing guide arm and feedstock channel, the fixed bracing piece that is provided with in the inside bottom surface left and right sides of device body, and the fixed pulley that is provided with in top of bracing piece, the inside top of device body is run through and is provided with spacing guide arm, and just the left end of spacing guide arm is connected in the output shaft outer wall of motor through master gear meshing, the inside left side top of device body is rotated and is provided with the pivot, and the bottom of pivot is connected in the outer wall of spacing guide arm through conical gear meshing. This industry solid waste processing is with zinc ingot classifying screen divides device, through the inside screening bucket of device body and the opposite rotation of rotating the guide arm, realizes mixing the screening to solid zinc ingot, sets up the unloading that the feed opening realized different specification zinc ingots through screening barrel bottom, realizes the multistage screening of different specification zinc ingots.

Description

Zinc ingot classifying and screening device for industrial solid waste processing

Technical Field

The utility model relates to an industry solid waste processing technology field specifically is a zinc ingot classifying and screening device is used in industry solid waste processing.

Background

The industrial solid waste processing generally refers to waste materials left in the industrial production process, and is various waste residues, dust and other waste materials discharged into the environment in the industrial production process, and the waste materials can be used after being processed again, particularly, the zinc ingot production needs to reach certain purity, and the zinc ingot with insufficient purity can be used after being processed again.

However, most industrial zinc ingot solid wastes have certain errors in the screening process, so that zinc ingots which do not meet the purity standard need to be returned to a furnace for re-feeding, zinc ingots with different specifications and sizes need to be screened before the waste zinc ingots are refined, zinc ingots with different specifications and sizes are purified after being distinguished according to the specifications of different zinc ingots, and the zinc ingots with different specifications are omitted in the screening process, so that the screening efficiency and precision are reduced.

Therefore, we propose a zinc ingot classifying and screening device for industrial solid waste processing so as to solve the problems proposed in the above.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an industry solid waste processing is with zinc ingot classifying screen divides device, with solve present most industry zinc ingot solid waste in the current market that above-mentioned background art provided in screening course of working, because there is certain error in the purity of the zinc ingot of producing, this zinc ingot that just makes and is not conform to the purity standard needs the material of carrying again in the time of going back to the stove, need sieve different specification size's zinc ingot before refining waste material zinc ingot again, purify again after distinguishing according to the specification of different zinc ingots, and the zinc ingot of different specifications also can appear omitting in screening process, lead to reducing the problem of screening efficiency and precision.

In order to achieve the above object, the utility model provides a following technical scheme: a zinc ingot grading and screening device for processing industrial solid waste comprises a device body, an air pump, a limiting guide rod and a feeding channel, wherein supporting rods are fixedly arranged on the left side and the right side of the inner bottom surface of the device body, pulleys are fixedly arranged at the tops of the supporting rods, a rotary guide rod penetrates through the left side of the inner portion of the device body, an air supply outlet is formed in the rotary guide rod, the left end of the rotary guide rod outside the device body is fixedly connected to the end portion of an output shaft of a motor, a screening barrel is rotatably arranged on the outer wall of the rotary guide rod inside the device body, a spiral auger is fixedly arranged on the outer wall of the rotary guide rod, the air pump is fixedly arranged at the end portion of the rotary guide rod outside the right side of the device body, a feeding hole is formed in the left side of the top of the screening barrel, a primary blanking hole is formed in the left side of the bottom of the screening barrel, and a middle-grade blanking hole is formed in the central position of the bottom of the screening barrel, and the bottom right side of screening bucket has seted up senior feed opening, and the bottom of screening bucket is provided with the bearing case simultaneously, the inside top of device body is run through and is provided with spacing guide arm, and the left end of spacing guide arm passes through the master gear meshing and connects in the output shaft outer wall of motor to the left and right sides outer wall of spacing guide arm passes through pinion meshing and connects in the left and right sides outer wall of screening bucket, the inside left side top of device body is rotated and is provided with the pivot, and the bottom of pivot is connected in the outer wall of spacing guide arm through the conical gear meshing, and the top of device body is run through and is provided with feedstock channel, and feedstock channel's inside rotation is provided with the dredging rod moreover, and the bottom of dredging rod passes through driving belt meshing simultaneously and connects in the outer wall of pivot.

Preferably, the bracing piece sets up about the vertical center axis symmetric distribution of device body, and for the slip setting of laminating each other between the top of bracing piece and the outer wall of screening bucket to mutually perpendicular sets up between the vertical center axis of bracing piece and the horizontal center axis of screening bucket.

Preferably, the rotary guide rod and the device body are arranged in a transverse and coaxial manner, the air supply outlets in the outer wall of the rotary guide rod are uniformly distributed in the outer wall of the rotary guide rod at equal intervals, and the spiral auger in the outer wall of the rotary guide rod and the screening barrel are arranged in a mutually-fitted manner in a rotating manner.

Preferably, be vertical coaxial distribution setting between feed port and the feedstock channel, and the inside mediation pole of feedstock channel is "L" font structure setting to the length of mediation pole equals feedstock channel's radius.

Preferably, elementary feed opening and middle level feed opening and hold and connect equidistant evenly distributed in the outer wall of screening bucket between the case to elementary feed opening and middle level feed opening and senior feed opening set up about holding between the case one-to-one.

Preferably, the horizontal central axis of the limiting guide rod and the horizontal central axis of the device body are distributed in parallel, and the limiting guide rods are arranged in a mutually opposite rotating mode.

Compared with the prior art, the beneficial effects of the utility model are that: according to the zinc ingot grading and screening device for processing industrial solid wastes, the solid zinc ingots are subjected to mixed screening through the reverse rotation of the screening barrel in the device body and the rotation guide rod, the blanking of the zinc ingots with different specifications is realized through the blanking port arranged at the bottom of the screening barrel, and the multi-stage screening of the zinc ingots with different specifications is realized;

1. the motor drives the limiting guide rod and the rotating shaft on the inner wall of the device body to rotate, and the rotating shaft drives the dredging rod in the feeding channel through the transmission belt to dredge the zinc ingots, so that the situation that the zinc ingots are blocked and cannot be screened is prevented, and the screening efficiency is accelerated;

2. through the inside rotation that runs through the rotating guide who sets up of device body for the spiral auger of rotating guide outer wall carries out the intensive mixing stirring to the zinc ingot, prevents that the light, small zinc ingot of quality can't obtain the screening, and rotation through spacing guide arm drives the screening bucket and carries out the opposite rotation, and the unloading is realized screening the unloading to the zinc ingot of different specifications after the feed opening of screening barrel head portion rotates to the bottom at every time.

Drawings

FIG. 1 is a schematic front view of the present invention;

FIG. 2 is a schematic view of the front section structure of the feeding channel of the present invention;

FIG. 3 is a schematic view of the front section structure of the sieving barrel of the present invention;

fig. 4 is a schematic structural diagram of a portion a in fig. 3 according to the present invention.

In the figure: 1. a device body; 2. a support bar; 3. a pulley; 4. rotating the guide rod; 5. an air delivery outlet; 6. a motor; 7. a screening barrel; 8. a spiral auger; 9. an air pump; 10. a feed port; 11. a primary feed opening; 12. a middle-level feed opening; 13. a high-grade feed opening; 14. a limiting guide rod; 15. a main gear; 16. a pinion gear; 17. a rotating shaft; 18. a feed channel; 19. and (4) dredging the rod.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-4, the present invention provides a technical solution: a zinc ingot grading screening device for processing industrial solid waste comprises a device body 1, an air pump 9, a limiting guide rod 14 and a feeding channel 18, wherein supporting rods 2 are fixedly arranged on the left side and the right side of the inner bottom surface of the device body 1, pulleys 3 are fixedly arranged at the top of the supporting rods 2, a rotary guide rod 4 penetrates through the left side of the inner portion of the device body 1, an air supply outlet 5 is formed in the rotary guide rod 4, the left end of the rotary guide rod 4 outside the device body 1 is fixedly connected to the end portion of an output shaft of a motor 6, a screening barrel 7 is rotatably arranged on the outer wall of the rotary guide rod 4 inside the device body 1, a spiral auger 8 is fixedly arranged on the outer wall of the rotary guide rod 4, the air pump 9 is fixedly arranged at the end portion of the rotary guide rod 4 outside the right side of the device body 1, a feeding hole 10 is formed in the left side of the top of the screening barrel 7, and a primary discharging hole 11 is formed in the left side of the bottom of the screening barrel 7, a middle-grade feed opening 12 is arranged at the center of the bottom of the screening barrel 7, a high-grade feed opening 13 is arranged at the right side of the bottom of the screening barrel 7, meanwhile, the bottom of the screening barrel 7 is provided with a receiving box, a limit guide rod 14 is arranged above the inner part of the device body 1 in a penetrating way, and the left end of the limit guide rod 14 is engaged with the outer wall of the output shaft of the motor 6 through a main gear 15, and the outer walls of the left and right sides of the limit guide rod 14 are engaged and connected with the outer walls of the left and right sides of the sieving barrel 7 through a pinion 16, a rotating shaft 17 is rotatably arranged above the left side of the inside of the device body 1, the bottom end of the rotating shaft 17 is engaged and connected with the outer wall of the limit guide rod 14 through a bevel gear, and the top of the device body 1 is provided with a feed channel 18 in a penetrating way, the inside of the feed channel 18 is rotatably provided with a dredging rod 19, and the bottom end of the dredging rod 19 is engaged and connected with the outer wall of the rotating shaft 17 through a transmission belt.

Bracing piece 2 sets up about the vertical center axis symmetric distribution of device body 1, and the slip setting for laminating each other between the top of bracing piece 2 and the outer wall of screening bucket 7 to mutually perpendicular sets up between the vertical central axis of bracing piece 2 and the horizontal central axis of screening bucket 7, prevents through bracing piece 2 that the rotation of screening bucket 7 from taking place to incline, supports screening bucket 7.

The rotary guide rod 4 and the device body 1 are arranged in a transverse and coaxial mode, the air supply outlets 5 in the outer wall of the rotary guide rod 4 are evenly distributed on the outer wall of the rotary guide rod 4 at equal intervals, and the spiral auger 8 in the outer wall of the rotary guide rod 4 and the screening barrel 7 are arranged in a mutually-fitted mode in a rotating mode to enable the spiral auger 8 to mix and stir zinc ingots inside the screening barrel 7.

The feed holes 10 and the feed channel 18 are arranged in a vertical coaxial manner, the dredging rods 19 in the feed channel 18 are arranged in an L-shaped structure, and the length of each dredging rod 19 is equal to the radius of the feed channel 18, so that the dredging rods 19 dredge the interior of the feed channel 18.

Equidistant evenly distributed between elementary feed opening 11 and middle level feed opening 12 and the senior feed opening 13 sieves the outer wall of bucket 7 to elementary feed opening 11 and middle level feed opening 12 and senior feed opening 13 are about holding the one-to-one setting between the case, accomodate the material through holding the case.

The horizontal central axis of spacing guide arm 14 and the horizontal central axis of device body 1 between parallel distribution set up each other, and each other is opposite rotation setting between spacing guide arm 14 and the screening bucket 7, drives screening bucket 7 through spacing guide arm 14 and rotates.

The working principle is as follows: before the zinc ingot grading and screening device for industrial solid waste processing is used, the overall condition of the device needs to be checked to determine that the device can normally work, according to the drawings of fig. 1-4, when zinc ingots need to be put into the device body 1, as shown in the drawings of fig. 1-2, a motor 6 and a main gear 15 on the left side of the device body 1 drive a limiting guide rod 14 penetrating through the device body 1 to rotate, the limiting guide rod 14 drives a rotating shaft 17 meshed with the limiting guide rod through a bevel gear to rotate, and then the rotating shaft 17 drives a dredging rod 19 rotatably arranged in a feeding channel 18 to rotate through a transmission belt, so that the zinc ingots are prevented from being blocked in the feeding channel 18;

as shown in fig. 3-4, the motor 6 on the left side of the device body 1 drives the rotary guide rod 4 to rotate, the rotary guide rod 4 drives the spiral auger 8 with the outer wall fixedly arranged to rotate, the motor 6 drives the limit guide rod 14 penetrating through the device body 1 to rotate through the main gear 15, the limit guide rod 14 drives the screening barrel 7 to rotate through the pinion 16, so that the rotation direction of the screening barrel 7 is opposite to that of the rotary guide rod 4, zinc ingots with different specifications are respectively discharged through the primary discharge opening 11, the intermediate discharge opening 12 and the high-grade discharge opening 13 on the outer wall of the screening barrel 7 through the rotation of the screening barrel 7 and the stirring and mixing of the spiral auger 8, and the mixing is prevented.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments or portions thereof without departing from the spirit and scope of the invention.

Claims (6)

1. The utility model provides an industry solid waste processing is with zinc ingot classifying screen device, includes device body (1), air pump (9), spacing guide arm (14) and feedstock channel (18), its characterized in that: the left side and the right side of the bottom surface inside the device body (1) are fixedly provided with supporting rods (2), the top of each supporting rod (2) is fixedly provided with a pulley (3), the left side inside the device body (1) is provided with a rotating guide rod (4) in a penetrating manner, an air supply outlet (5) is formed inside each rotating guide rod (4), the left end of each rotating guide rod (4) outside the device body (1) is fixedly connected to the end part of an output shaft of a motor (6), the outer wall of each rotating guide rod (4) inside the device body (1) is rotatably provided with a screening barrel (7), the outer wall of each rotating guide rod (4) is fixedly provided with a spiral auger (8), the end part of each rotating guide rod (4) outside the right side of the device body (1) is fixedly provided with an air pump (9), the left side of the top of each screening barrel (7) is provided with a feeding hole (10), and the left side of the bottom of each screening barrel (7) is provided with a primary discharging hole (11), a middle-level feed opening (12) is arranged at the central position of the bottom of the screening barrel (7), a high-level feed opening (13) is arranged at the right side of the bottom of the screening barrel (7), a receiving box is arranged at the bottom of the screening barrel (7), a limiting guide rod (14) penetrates through the upper part of the inside of the device body (1), the left end of the limiting guide rod (14) is meshed and connected with the outer wall of an output shaft of the motor (6) through a main gear (15), the outer walls of the left side and the right side of the limiting guide rod (14) are meshed and connected with the outer walls of the left side and the right side of the screening barrel (7) through a secondary gear (16), a rotating shaft (17) is rotatably arranged above the left side of the inside of the device body (1), the bottom end of the rotating shaft (17) is meshed and connected with the outer wall of the limiting guide rod (14) through a conical gear, and a feed channel (18) penetrates through the top of the device body (1), and the inside of the feeding channel (18) is rotatably provided with a dredging rod (19), and the bottom end of the dredging rod (19) is engaged and connected with the outer wall of the rotating shaft (17) through a transmission belt.

2. The zinc ingot classifying and screening device for industrial solid waste processing according to claim 1, wherein: the bracing piece (2) sets up about the vertical center axis symmetric distribution of device body (1), and the slip setting for laminating each other between the top of bracing piece (2) and the outer wall of screening bucket (7) to mutually perpendicular sets up between the vertical center axis of bracing piece (2) and the horizontal center axis of screening bucket (7).

3. The zinc ingot classifying and screening device for industrial solid waste processing according to claim 1, wherein: the device is characterized in that the rotary guide rod (4) and the device body (1) are arranged in a transverse and coaxial manner, air supply outlets (5) in the outer wall of the rotary guide rod (4) are uniformly distributed on the outer wall of the rotary guide rod (4) at equal intervals, and a spiral auger (8) in the outer wall of the rotary guide rod (4) and the screening barrel (7) are arranged in a mutually-fitted manner in a rotating manner.

4. The zinc ingot classifying and screening device for industrial solid waste processing according to claim 1, wherein: the feeding holes (10) and the feeding channel (18) are arranged in a vertical and coaxial mode, the dredging rods (19) inside the feeding channel (18) are arranged in an L-shaped structure, and the length of the dredging rods (19) is equal to the radius of the feeding channel (18).

5. The zinc ingot classifying and screening device for industrial solid waste processing according to claim 1, wherein: elementary feed opening (11) and middle level feed opening (12) and senior feed opening (13) between equidistance evenly distributed in the outer wall of screening bucket (7) to elementary feed opening (11) and middle level feed opening (12) and senior feed opening (13) are about accepting the one-to-one setting between the case.

6. The zinc ingot classifying and screening device for industrial solid waste processing according to claim 1, wherein: the transverse central axis of the limiting guide rod (14) and the transverse central axis of the device body (1) are arranged in parallel, and the limiting guide rod (14) and the screening barrel (7) are arranged in a mutually opposite rotating mode.

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