CN218962812U - Raw material multistage crushing device for iron oxide production - Google Patents

Abstract

The utility model discloses a raw material multistage crushing device for iron oxide production, which belongs to the technical field of iron oxide production and comprises a crushing cavity, a crushing device and a throwing and concentrating device, wherein the crushing cavity is horizontally arranged, the crushing device is arranged on the crushing cavity, the throwing and concentrating device is arranged on the crushing cavity, the crushing device comprises a driving component and a crushing component, the driving component is arranged at the upper end of the outer side of the crushing cavity, and the crushing component is arranged in the crushing cavity.

Description

Raw material multistage crushing device for iron oxide production

Technical Field

The utility model relates to the technical field of iron oxide production, in particular to a raw material multistage crushing device for iron oxide production.

Background

Iron oxide, named ferric oxide, limonite, haematitum, plumbum Preparatium, iron red, red powder, and Venetian red (mainly comprising ferric oxide). The chemical formula Fe2O3 is dissolved in hydrochloric acid and is reddish brown powder. The reddish brown powder is a low-grade pigment, is industrially called ferric oxide red, is used in the industries of paint, printing ink, rubber and the like, can be used as a catalyst, can be used as a polishing agent for glass, precious stone and metal, can be used as an iron-making raw material, and is widely used as an inorganic pigment for coloring various products in the paint industry, the printing ink industry, the rubber industry and the plastic industry.

The existing raw materials for iron oxide production are crushed after being crushed, the raw materials cannot be crushed for the second time, and the raw materials cannot be mixed and stirred in the secondary crushing process, so that the crushing is completed unevenly, and therefore equipment capable of crushing the raw materials for iron oxide production for the second time and stirring evenly is lacking.

Disclosure of Invention

The embodiment of the utility model provides a raw material multi-stage crushing device for iron oxide production, which aims to solve the technical problems.

The embodiment of the utility model adopts the following technical scheme: including crushing cavity, breaker and throwing in centralized arrangement, the crushing cavity is the level setting, breaker sets up on crushing cavity, throw in centralized arrangement and set up on crushing cavity, breaker includes drive assembly and crushing assembly, drive assembly sets up the upper end in the crushing cavity outside, crushing assembly sets up the inside at crushing cavity.

Further, the drive assembly includes drive cavity, driving motor, drive frame, drive shaft, actuating post, drive half gear, drive gear and actuating lever, the drive cavity sets up the upper end at broken cavity, driving motor sets up the inside at the drive cavity, the drive frame sets up on the inside wall of drive cavity, driving motor's output passes the drive frame, drive shaft connection is on driving motor's output, the actuating post cover is established in the drive shaft, the drive half gear sets up the lower extreme at the drive shaft, the one end of actuating lever is located the drive cavity and the other end passes drive cavity and broken cavity, the drive gear cover is established on the one end of actuating lever and is located the drive cavity, drive gear and drive half gear engagement, be equipped with the tooth with the drive gear engagement on the actuating post, tooth on the actuating post is the same with tooth orientation on the drive half gear.

Further, the crushing assembly comprises crushing blades and mixing blades, wherein the crushing blades are sleeved on the driving rod and located in the throwing and concentrating device, and the mixing blades are sleeved on the driving rod and located below the crushing blades.

Further, put in centralized arrangement and put in the cavity including putting in the pipeline, evenly be equipped with a plurality of on the broken cavity and put in the mouth, put in the pipeline and be equipped with a plurality of, a plurality of put in the pipeline all set up in the mouth lower extreme of putting in corresponding, put in the cavity setting at a plurality of put in the lower extreme of pipeline, a plurality of put in the pipeline and be the slope setting, broken blade is located the inside of putting in the cavity, the actuating lever passes and puts in the cavity and not with put in the cavity contact, the lower extreme of putting in the cavity is equipped with the opening.

Further, a discharge hole is formed in the lower end of the crushing cavity.

The above at least one technical scheme adopted by the embodiment of the utility model can achieve the following beneficial effects:

firstly, when the raw materials for producing iron oxide are put into the crushing cavity for crushing, firstly, the raw materials for producing iron oxide which are needed to be different are put into the crushing cavity through the plurality of putting openings, at the moment, the raw materials for producing iron oxide can flow into the putting cavity through the putting pipeline in a collecting mode, at the moment, the raw materials for producing iron oxide which are positioned in the putting cavity are subjected to primary crushing through the crushing blades, after the raw materials for producing iron oxide in the putting cavity are subjected to primary crushing, the raw materials for producing iron oxide flow into the crushing cavity through the opening in the putting cavity, so that the raw materials for producing iron oxide which are subjected to primary crushing flow into the center of the crushing cavity, at the moment, the raw materials for producing iron oxide are subjected to secondary crushing through the rotation of the mixing blades and the stirring and mixing of the mixing blades, and the raw materials for producing iron oxide can be fully crushed and mixed in the crushing cavity through mutual impact and the mutual rotation of the crushing blades, and the crushing and the mixing are uniform, and the processing efficiency is improved.

Secondly, when the raw materials for producing the iron oxide are placed into the crushing cavity through the throwing and concentrating device, the crushing blades and the mixing blades are driven to synchronously rotate forwards through the forward rotation of the driving rod, and after the forward rotation of the driving rod is finished, the driving rod synchronously drives the crushing blades and the mixing blades to synchronously rotate reversely through the reverse rotation of the driving rod, so that the raw materials for producing the iron oxide in the crushing cavity are rapidly crushed, the raw materials for producing the iron oxide are fully crushed by mutual impact in the crushing cavity, and are uniformly crushed, and the raw materials for producing the iron oxide are subjected to secondary crushing and stirring mixing after primary crushing in the crushing cavity are finished at the same time of primary crushing, so that the processing efficiency is improved.

Thirdly, after the raw materials for producing the ferric oxide are crushed, the required storage equipment is placed under the discharge hole, and then the discharge hole is opened, so that the raw materials for producing the ferric oxide, which are crushed, can be collected.

Drawings

The accompanying drawings, which are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this specification, illustrate embodiments of the utility model and together with the description serve to explain the utility model and do not constitute a limitation on the utility model. In the drawings:

FIG. 1 is a schematic view of a broken-away structure of a crushing cavity of the present utility model;

FIG. 2 is a schematic diagram of a driving assembly according to the present utility model;

FIG. 3 is a schematic view of a crushing device according to the present utility model;

FIG. 4 is a schematic view of the structure of the crushing device and the throwing and concentrating device in the utility model;

fig. 5 is a schematic perspective view of the present utility model.

Reference numerals

Crushing cavity 1, delivery port 11, discharge port 12, crushing device 2, drive assembly 21, drive cavity 211, drive motor 212, drive rack 213, drive shaft 214, drive column 215, drive half gear 216, drive gear 217, drive rod 218, crushing assembly 22, crushing blade 221, mixing blade 222, delivery concentrator 3, delivery pipe 31, and delivery cavity 32.

Detailed Description

In order to make the objects, technical solutions and advantages of the present utility model more apparent, the technical solutions of the present utility model will be clearly and completely described below with reference to specific embodiments of the present utility model and corresponding drawings. It will be apparent that the described embodiments are only some, but not all, embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

The following describes in detail the technical solutions provided by the embodiments of the present utility model with reference to the accompanying drawings.

The embodiment of the utility model provides a raw material multistage crushing device for iron oxide production, which comprises a crushing cavity 1, a crushing device 2 and a throwing and concentrating device 3, wherein the crushing cavity 1 is horizontally arranged, the crushing device 2 is arranged on the crushing cavity 1, the throwing and concentrating device 3 is arranged on the crushing cavity 1, the crushing device 2 comprises a driving component 21 and a crushing component 22, the driving component 21 is arranged at the upper end of the outer side of the crushing cavity 1, the crushing component 22 is arranged in the crushing cavity 1, raw materials can be crushed quickly through the crushing device, and after the crushing is finished, the raw materials flow into the crushing cavity to be crushed again while being stirred, and the raw materials are fully and uniformly mixed and crushed, so that the processing efficiency is improved, and the subsequent processing operation is facilitated.

Preferably, the driving assembly 21 comprises a driving cavity 211, a driving motor 212, a driving frame 213, a driving shaft 214, a driving column 215, a driving half gear 216, a driving gear 217 and a driving rod 218, wherein the driving cavity 211 is arranged at the upper end of the crushing cavity 1, the driving motor 212 is arranged inside the driving cavity 211, the driving frame 213 is arranged on the inner side wall of the driving cavity 211, the output end of the driving motor 212 passes through the driving frame 213, the driving shaft 214 is connected to the output end of the driving motor 212, the driving column 215 is sleeved on the driving shaft 214, the driving half gear 216 is arranged at the lower end of the driving shaft 214, one end of the driving rod 218 is positioned in the driving cavity 211, the other end of the driving rod 218 passes through the driving cavity 211 and the crushing cavity 1, the driving gear 217 is sleeved on one end of the driving rod 218 and is positioned in the driving cavity 211, the driving gear 217 is meshed with the driving half gear 216, the driving column 215 is provided with teeth meshed with the driving gear 217, the teeth on the driving column 215 and the teeth on the driving half gear 216 face the same direction, when the crushing assembly 22 needs to be started, the driving motor 212 is firstly operated to drive the driving shaft 214 on the output end of the driving motor 212 to rotate, the driving shaft 214 rotates to drive the driving column 215 and the driving half gear 216 to synchronously rotate, when the teeth on the driving column 215 are meshed with the teeth on the driving gear 217, the driving column 215 rotates to drive the driving gear 217 to positively rotate, when the teeth on the driving half gear 216 are meshed with the teeth on the driving gear 217, the driving half gear 216 rotates to drive the driving gear 217 to reversely rotate, and when the driving gear 217 positively rotates and reversely rotates, the driving rod 218 is synchronously driven to positively rotate and reversely rotate, thereby driving the crushing assembly 22 to operate so as to crush, stir and mix the raw materials for producing the iron oxide in the crushing cavity 1.

Preferably, the crushing assembly 22 includes a crushing blade 221 and a mixing blade 222, the crushing blade 221 is sleeved on the driving rod 218 and is located in the feeding and concentrating device 3, the mixing blade 222 is sleeved on the driving rod 218 and is located below the crushing blade 221, when the raw material for producing iron oxide is put into the crushing cavity 1 through the feeding and concentrating device 3, the driving rod 218 rotates forward to drive the crushing blade 221 and the mixing blade 222 to rotate synchronously forward, after the driving rod 218 rotates forward, the driving rod 218 rotates reversely immediately and then synchronously drives the crushing blade 221 and the mixing blade 222 to rotate synchronously reversely, so that the raw material for producing iron oxide in the crushing cavity 1 is crushed rapidly, the raw material for producing iron oxide is fully crushed in the crushing cavity 1 by mutual impact, and the crushing is uniform, so that the processing efficiency is improved.

Preferably, put in centralized device 3 and put in cavity 32 including putting in pipeline 31, evenly be equipped with a plurality of on the crushing cavity 1 and put in mouth 11, put in pipeline 31 and be equipped with a plurality of, a plurality of put in pipeline 31 all sets up and put in mouth 11 lower extreme that corresponds, put in the cavity 32 set up a plurality of put in the lower extreme of pipeline 31, a plurality of put in pipeline 31 all is the slope setting, crushing blade 221 is located the inside of putting in cavity 32, actuating lever 218 passes and puts in cavity 32 and not with putting in cavity 32 contact, put in the lower extreme of cavity 32 and be equipped with the opening, when putting in crushing cavity 1 inside with the raw materials for iron oxide production and put in the crushing, put in mouthful 11 through a plurality of with the raw materials for iron oxide production that needs at first, the raw materials for iron oxide production can flow into and put in cavity 32 through putting in pipeline 31 collection at this moment, lie in the inside raw materials for iron oxide production of putting in cavity 32 and carry out preliminary crushing through crushing blade, put in the inside crushing blade and put in the crushing cavity 32 and put in the crushing blade, through the crushing blade and the crushing blade is just can be mixed evenly to the crushing cavity 1, and mix the crushing cavity is just through the crushing blade is just mixed to the crushing cavity is just mixed, and the mixed well is mixed to the crushing cavity is opened, and the crushing cavity is just mixed to the crushing 1 is just mixed to the raw materials is just mixed.

Preferably, the lower end of the crushing cavity 1 is provided with a discharge hole 12, after the raw material for producing the ferric oxide is crushed, the required storage equipment is placed under the discharge hole 12, and then the discharge hole 12 is opened, so that the raw material for producing the ferric oxide, which is crushed, can be collected.

The foregoing is merely exemplary of the present utility model and is not intended to limit the present utility model. Various modifications and variations of the present utility model will be apparent to those skilled in the art. Any modification, equivalent replacement, improvement, etc. which come within the spirit and principles of the utility model are to be included in the scope of the claims of the present utility model.

Claims (3)

1. The utility model provides a raw materials multistage reducing mechanism for ferric oxide production, its characterized in that includes crushing cavity (1), crushing device (2) and puts in centralized arrangement (3), crushing cavity (1) is the level setting, crushing device (2) set up on crushing cavity (1), put in centralized arrangement (3) and set up on crushing cavity (1), crushing device (2) include drive assembly (21) and crushing assembly (22), drive assembly (21) set up the upper end in crushing cavity (1) outside, crushing assembly (22) set up the inside in crushing cavity (1), drive assembly (21) include drive cavity (211), driving motor (212), drive frame (213), drive shaft (214), drive post (215), drive half gear (216), drive gear (217) and actuating lever (218), drive cavity (211) set up the upper end in crushing cavity (1), driving motor (212) set up the inside in drive cavity (211), drive motor (213) set up on the drive end in drive frame (212) output of drive (213) and pass through on the output end of drive frame (212), the utility model provides a drive post (215) cover is established on drive shaft (214), drive half gear (216) set up the lower extreme on drive shaft (214), the one end of actuating lever (218) is located actuating chamber (211) and the other end passes actuating chamber (211) and crushing cavity (1), drive gear (217) cover is established on the one end of actuating lever (218) and is located actuating chamber (211), drive gear (217) and drive half gear (216) meshing, be equipped with the tooth with drive gear (217) meshing on drive post (215), tooth on drive post (215) is the same with the tooth orientation on drive half gear (216), crushing subassembly (22) are including crushing blade (221) and hybrid blade (222), crushing blade (221) cover are established on actuating lever (218) and are located the inside of throwing centralized arrangement (3), hybrid blade (222) cover is established on actuating lever (218) and is located the below of crushing blade (221).

2. The raw material multi-stage crushing device for iron oxide production according to claim 1, wherein the throwing concentration device (3) comprises a throwing pipeline (31) and a throwing cavity (32), a plurality of throwing openings (11) are uniformly formed in the crushing cavity (1), the throwing pipeline (31) is provided with a plurality of throwing openings (11), the throwing cavities (32) are formed in the lower ends of the corresponding throwing openings (11), the throwing cavities (31) are formed in the lower ends of the throwing pipelines (31), the throwing pipelines (31) are obliquely arranged, the crushing blades (221) are located in the throwing cavities (32), and the driving rods (218) penetrate through the throwing cavities (32) and are not in contact with the throwing cavities (32), and openings are formed in the lower ends of the throwing cavities (32).

3. The raw material multistage grinding device for iron oxide production according to claim 1, wherein a discharge port (12) is arranged at the lower end of the grinding cavity (1).

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