CN112337615B - Hot air device for drying bentonite additive - Google Patents

Abstract

The invention discloses a hot air device for drying bentonite additives, which comprises a crushing bin, wherein the crushing bin is provided with a crushing cavity, the bottom of the crushing cavity is provided with a metal screen, the hot air device for drying bentonite additives further comprises a crushing assembly sliding in the crushing bin, the crushing assembly is used for crushing bentonite additives added into the crushing cavity, the device further comprises vibration blanking assemblies assembled on the front side and the rear side of the crushing bin, the vibration blanking assemblies comprise mounting seat plates fixedly connected to the left end and the right end of the crushing bin, vibration girder columns are fixedly connected between the crushing bin, vibration motors are assembled on the vibration girder columns, the device further comprises a drying assembly assembled at the lower end of the crushing bin, the drying assembly comprises a drying bin, and a hot air drying component is assembled in the drying bin. The crushing, sieving and drying integrated device is realized by adopting the device component design, and the device component design is convenient to operate, so that the material processing can be realized rapidly and effectively.

Description

Hot air device for drying bentonite additive

Technical Field

The invention relates to the field of bentonite additive processing devices, in particular to a hot air device for drying a bentonite additive.

Background

Bentonite is a clay rock, also called montmorillonite clay rock, and often bentonite contains a small amount of illite, kaolinite, halloysite, chlorite, zeolite, quartz, feldspar, calcite, and the like; is generally white and light yellow, and is light gray, light green, pink, brown red, brick red, gray black and the like due to the change of iron content; waxy, earthen or greasy luster; bentonite is loose like earth and dense and hard. The main chemical components are silicon dioxide, aluminum oxide and water, and also contain elements such as iron, magnesium, calcium, sodium, potassium and the like.

Bentonite has a very wide range of applications in industry, such as use as an adsorbent.

In the prior art, various additives are often required to be added into bentonite in the process of processing and producing bentonite products so as to improve the performance of the products.

In the processing process, the additive is mixed with bentonite in a mixing mode according to a certain proportion, the additive is required to be properly crushed before mixing, the crushed materials are required to be screened, and the screened materials are required to be dried, however, the device disclosed in the prior art is mainly in an independent process mode, so that the processed materials such as the crushed materials are required to be continuously conveyed to a screening device for screening, the screened materials are conveyed to a drying device for drying, and the processing efficiency is low.

Disclosure of Invention

The invention aims to solve the technical problem of providing a hot air device for drying bentonite additives.

The invention solves the technical problems through the following technical scheme:

the hot air device for drying the bentonite additive comprises a crushing bin, wherein the crushing bin is provided with a crushing cavity, and the bottom of the crushing cavity is provided with a metal screen;

the hot air device for drying the bentonite additive further comprises a crushed aggregates component sliding in the crushed aggregates bin; the crushed aggregates assembly is used for crushing bentonite additives added into the crushed aggregates cavities;

the hot air device for drying the bentonite additive further comprises vibration blanking components which are assembled on the front side and the rear side of the crushing bin;

the vibration blanking assemblies comprise mounting seat plates fixedly connected to the left end and the right end of the crushing bin, vibration girder columns are fixedly connected between the crushing bins, and vibration motors are assembled on the vibration girder columns;

the hot air device for drying the bentonite additive further comprises a drying assembly arranged at the lower end of the crushing bin;

the drying assembly comprises a drying bin, and a hot air drying component is assembled in the drying bin;

the hot air drying component comprises a serpentine drying pipe, and a plurality of exhaust through holes are formed in the serpentine drying pipe;

and an air inlet end of the serpentine drying pipe is provided with an air heater.

Preferably, the crushing assembly comprises a plurality of U-shaped sliding rods with downward openings, and the U-shaped sliding rods are assembled into a whole through a plurality of mounting plates;

the bottom of the U-shaped slide bar is fixedly connected with a plurality of crushed aggregates parts which are arranged at intervals in the front-back direction, each crushed aggregates part comprises a long screw rod assembled on the U-shaped slide bar, and a plurality of crushed aggregates parts which are arranged at intervals in the upper-lower direction are assembled on the long screw rods;

the crushing pieces comprise arc rods, and a plurality of crushing cones are fixedly connected to the side walls of the arc rods;

the crushing assembly further comprises a driving part for driving the U-shaped sliding rods, and the U-shaped sliding rods are used for carrying crushed aggregates of crushed aggregates.

Preferably, a plurality of upright posts are fixedly connected between the bottom of the crushing bin and the top of the drying bin;

the upright post is welded between the crushed aggregates bin and the drying bin.

Preferably, the exhaust through holes are horizontally arranged on the serpentine drying pipe.

Preferably, the U-shaped sliding rod comprises a horizontal end, sliding ends which are vertically downwards arranged are arranged at the front end and the rear end of the horizontal end, sliding grooves matched with the sliding ends are formed in the front side and the rear side of the top of the crushing bin, and the sliding ends slide in the sliding grooves;

the long screw is connected to the horizontal end in a threaded manner.

Preferably, the long screw is in threaded connection with a plurality of interval adjusting nuts;

the upper end parts of the arc-shaped rods are respectively provided with a sliding part which is horizontally arranged, and the sliding parts are in sliding connection with the long screw rods;

the plurality of interval adjusting nuts are respectively extruded at the top and the bottom of the sliding part.

Preferably, the cambered surface of the arc-shaped rod is arranged towards the left.

Preferably, a plurality of crushing cones are distributed on the cambered surface of the cambered rod in an arc shape; the driving part comprises a screw rod which is connected with the front ends of the plurality of U-shaped slide bars in a threaded manner;

the screw rod is in threaded connection with the sliding end of the arc-shaped rod;

the left end of the screw rod is rotationally connected to the left groove wall of the chute;

the right end of the screw rod penetrates through the sliding groove, and a screw rod motor is arranged at the right end of the screw rod.

Preferably, the rear sides of the plurality of U-shaped sliding rods are connected with guide rods in a sliding way;

the guide rods penetrate through the sliding ends of the U-shaped sliding rods;

the left end and the right end of the guide rod are respectively and fixedly connected to the left groove wall and the right groove wall of the chute.

Preferably, the front and rear ends of the tops of the plurality of U-shaped slide bars are respectively provided with mounting plates;

the mounting plate is assembled and connected to the U-shaped slide bars through mounting bolts. .

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

the invention discloses a hot air device for drying bentonite additives, which is characterized in that a crushing bin is designed, wherein the crushing bin is provided with a crushing cavity, the bottom of the crushing cavity is provided with a metal screen, the hot air device for drying the bentonite additives also comprises a crushing component which slides in the crushing bin, the crushing component is used for adding the bentonite additives into the crushing cavity, the hot air device for drying the bentonite additives also comprises vibrating blanking components which are assembled at the front side and the rear side of the crushing bin, the vibrating blanking components respectively comprise mounting seat plates fixedly connected with the left end and the right end of the crushing bin, a vibrating girder column is fixedly connected between the crushing bins, the vibrating girder column is provided with a vibrating motor, the hot air device for drying the bentonite additives also comprises a drying component which is assembled at the lower end of the crushing bin, the drying component comprises a drying bin, and the drying bin is internally provided with a hot air drying component so as to realize crushing, sieving and drying integration through the design of the components.

The crushing, sieving and drying integrated device is realized by adopting the device component design, and the device component design is convenient to operate, so that the material processing can be realized rapidly and effectively.

Drawings

FIG. 1 is a schematic overall structure of an embodiment of the present invention;

FIG. 2 is a schematic view of a crushing assembly according to an embodiment of the present invention;

FIG. 3 is a schematic view of a crushing member according to an embodiment of the present invention;

FIG. 4 is a schematic view of the dispersion structure in FIG. 1 according to an embodiment of the present invention;

FIG. 5 is a schematic plan view of a hot air drying section according to an embodiment of the present invention;

fig. 6 is an enlarged view of the structure of the crushing member in the embodiment of the present invention.

Detailed Description

The following describes in detail the examples of the present invention, which are implemented on the premise of the technical solution of the present invention, and detailed embodiments and specific operation procedures are given, but the scope of protection of the present invention is not limited to the following examples.

As shown in fig. 1 to 5, a hot air device for drying bentonite additives comprises a crushing bin 1, wherein the crushing bin 1 is provided with a crushing cavity, and the bottom of the crushing cavity is provided with a metal screen 12.

The hot air device for drying the bentonite additive also comprises a crushed aggregates component sliding in the crushed aggregates bin 1; the crushed aggregates subassembly is used for crushed aggregates to add the bentonite additive in the crushed aggregates chamber, and the bentonite additive is crushed through the crushed aggregates subassembly.

In order to realize rapid blanking of crushed materials, the hot air device for drying bentonite additives further comprises vibration blanking components 5 which are assembled at the front side and the rear side of the crushing bin 1. And the blanking is vibrated by the vibration blanking assembly 5.

The specific structure of the vibration blanking assembly 5 is as follows:

the vibration unloading assembly 5 comprises mounting seat boards 53 fixedly connected to the left end and the right end of the crushing bin 1, a vibration girder column 51 is fixedly connected between the crushing bins 1, and a vibration motor 52 is assembled on the vibration girder column 51.

After the materials are crushed, the vibrating motors 52 at the two sides are opened, the vibrating motors 52 vibrate the vibrating girder columns 51, and then the whole crushing bin 1 vibrates, and in the vibration process, the materials are discharged from the metal screen 12.

The hot air device for drying the bentonite additive also comprises a drying assembly which is assembled at the lower end of the crushing bin 1; the concrete assembly mode is as follows: a plurality of upright posts 6 are fixedly connected between the bottom of the crushing bin 1 and the top of the drying bin; the upright post 6 is welded between the crushed aggregates bin 1 and the drying bin.

The drying assembly comprises a drying bin 7, and a hot air drying part 8 is assembled in the drying bin 7;

the hot air drying part 8 comprises a serpentine drying pipe 82, and a plurality of air exhaust through holes 821 are formed in the serpentine drying pipe 82 (the air exhaust through holes 821 are horizontally arranged on the serpentine drying pipe 82).

The air inlet end of the serpentine drying pipe 82 is provided with an air heater 81, specifically, the air outlet end of the air heater 81 is communicated with the air inlet end of the serpentine drying pipe 82 through a transfer pipeline 811.

The material subjected to vibration blanking enters the drying bin 7, at the moment, the hot air blower 81 is turned on, the hot air blower 81 pumps hot air into the drying bin 7, and hot air flow is discharged from the air exhaust through hole 821, and the sieved material has smaller particle size, so that the material can be dried after contacting the hot air flow.

In the actual working process, a cloth enclosing block (not shown in the figure) is fixedly connected between the bottom of the crushed aggregates bin 1 and the drying bin 7, the upright posts 6 are enclosed in the cloth enclosing block, and then in hot air drying, dust is reduced and discharged into a workshop.

In order to crush materials, the hot air device for drying the bentonite additive also comprises a crushed material assembly sliding in the crushed material bin 1; the crushed aggregates subassembly realizes automatic turning and crushing. The specific structure of the crushed aggregates assembly is as follows:

the crushed aggregates subassembly includes a plurality of opening U-shaped slide bar 31 that sets up down (specifically, U-shaped slide bar 31 includes the horizontal end, both ends have the slip end that sets up down perpendicularly around the horizontal end, the spout 11 with slip end complex is seted up to both sides around the crushed aggregates storehouse 1 top, the slip end slides in spout 11).

The plurality of U-shaped sliding rods 31 are assembled into a whole through a plurality of mounting plates 32; the specific method is as follows: the front and rear ends of the tops of the plurality of U-shaped sliding rods 31 are respectively provided with a mounting plate 32; the mounting plate 32 is assembled and connected to a plurality of the U-shaped slide bars 31 by mounting bolts.

The bottom of the U-shaped slide bar 31 is fixedly connected with a plurality of material crushing parts 33 which are arranged at intervals front and back.

The particle members 33 each comprise a long screw 331 mounted on a U-shaped slide bar 31 in the following manner: a long screw 331 is screwed on the horizontal end of the U-shaped slide bar 31.

The long screw 331 is provided with a plurality of material crushing pieces 332 which are arranged at intervals up and down; the particle pieces 332 each include an arc rod 3321, and a plurality of particle cones 3322 are fixedly connected to a side wall of the arc rod 3321 (specifically, an arc surface of the arc rod 3321 is set to the left, and a plurality of particle cones 3322 are arcuately distributed on an arc surface of the arc rod 3321), as shown in fig. 6 in detail.

The above-mentioned crushed aggregates assembly further comprises a driving part 4 for driving a plurality of the U-shaped slide bars 31, and the crushed aggregates 332 are carried by the driving part 4 and the plurality of the U-shaped slide bars 31.

In the actual working process, according to the amount of the materials added into the particle bin 1, the height interval between the upper and lower parts of the particle pieces 332 is adjusted, and the following manner is adopted:

the long screw 331 is connected with a plurality of interval adjusting nuts 3311 in a threaded manner; the upper end parts of the arc-shaped rods 3321 are respectively provided with a sliding part which is horizontally arranged and is in sliding connection with the long screw 331; a plurality of the interval adjusting nuts 3311 are respectively pressed on the top and bottom of the sliding part.

The arc-shaped rod 3321 slides on the long screw 331 by loosening the interval adjusting nut 3311, and after the interval is adjusted, the interval adjusting nut 3311 is screwed and pressed on the sliding part of the arc-shaped rod 3321 to realize positioning.

The driving part 4 drives the whole crushing assembly to move left and right, and in the moving process, the arc rod 3321 carries the crushing cone 3322 to move left and right, and in the process, the material is turned over, and the deblocking material is crushed in the turning process to form small pieces of material.

The specific structure of the driving part 4 is as follows: the screw rods 42 are connected to the front ends of the plurality of U-shaped slide rods 31 in a threaded manner; the screw rod 42 is in threaded connection with the sliding end of the arc-shaped rod 3321; the left end of the screw rod 42 is rotatably connected to the left groove wall of the chute 11 in the conventional manner; the right end of the screw 42 penetrates through the chute 11, and the right end of the screw 42 is provided with a screw motor 41. The screw motor 41 is turned on (the screw motor 41 is preferably a forward and reverse rotation motor), the screw motor 41 drives the screw 42 to rotate, and then the whole crushed aggregates assembly moves left and right to turn over and crush materials.

In order to increase the stability of the driving motion, the rear side of the plurality of U-shaped slide bars 31 is slidingly connected with a guide bar 43; the guide rod 43 penetrates through the sliding ends of the U-shaped sliding rods 31; the left and right ends of the guide rod 43 are fixedly connected to the left and right groove walls of the chute 11, respectively.

Adopt above-mentioned device part design not only can be quick effectual realization in bentonite additive course of working, turn over the material with bentonite additive and broken, be convenient for the material after the breakage simultaneously sieve, be convenient for the material stoving after sieving, consequently, above-mentioned device part design realizes breakage, sieve, dry integration, and above-mentioned device part design convenient operation can effectively realize the material processing fast.

In actual work, in order to facilitate feeding, a feeding trough plate is fixedly connected to the left end of the crushing bin 1, the feeding trough plate comprises vertical plate parts 21 which are arranged at intervals front and back, and a sliding plate part 22 which is arranged obliquely downwards is arranged between the vertical plate parts 21; a support rod part 23 is fixedly connected between the front side and the rear side of the bottom of the slide plate part 22. The material slides from the slide plate portion 22 for blanking.

The foregoing description of the preferred embodiments of the invention is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the invention.

Claims (9)

1. The hot air device for drying the bentonite additive is characterized by comprising a crushing bin, wherein the crushing bin is provided with a crushing cavity, and the bottom of the crushing cavity is provided with a metal screen;

the hot air device for drying the bentonite additive further comprises a crushed aggregates component sliding in the crushed aggregates bin; the crushed aggregates assembly is used for crushing bentonite additives added into the crushed aggregates cavities;

the hot air device for drying the bentonite additive further comprises vibration blanking components which are assembled on the front side and the rear side of the crushing bin;

the vibration blanking assemblies comprise mounting seat plates fixedly connected to the left end and the right end of the crushing bin, vibration girder columns are fixedly connected between the mounting seat plates, and vibration motors are assembled on the vibration girder columns;

the hot air device for drying the bentonite additive further comprises a drying assembly arranged at the lower end of the crushing bin;

the drying assembly comprises a drying bin, and a hot air drying component is assembled in the drying bin;

the hot air drying component comprises a serpentine drying pipe, and a plurality of exhaust through holes are formed in the serpentine drying pipe;

an air inlet end of the serpentine drying pipe is provided with an air heater; the crushing assembly comprises a plurality of U-shaped sliding rods with downward openings, and the U-shaped sliding rods are assembled into a whole through a plurality of mounting plates;

the bottom of the U-shaped slide bar is fixedly connected with a plurality of crushed aggregates parts which are arranged at intervals in the front-back direction, each crushed aggregates part comprises a long screw rod assembled on the U-shaped slide bar, and a plurality of crushed aggregates parts which are arranged at intervals in the upper-lower direction are assembled on the long screw rods;

the crushing pieces comprise arc rods, and a plurality of crushing cones are fixedly connected to the side walls of the arc rods;

the crushed aggregates assembly further comprises a driving part for driving the plurality of U-shaped sliding rods, and crushed aggregates of crushed aggregates are carried by the plurality of U-shaped sliding rods through the driving part;

the air outlet end of the air heater is communicated with the air inlet end of the serpentine drying pipe through a transfer pipeline;

and a cloth enclosing block is fixedly connected between the bottom of the crushed aggregates bin and the drying bin, and the upright posts are enclosed in the cloth enclosing block.

2. The bentonite additive drying hot air device according to claim 1, wherein a plurality of upright posts are fixedly connected between the bottom of the crushing bin and the top of the drying bin;

the upright post is welded between the crushed aggregates bin and the drying bin.

3. The bentonite additive drying hot air apparatus according to claim 2, wherein the exhaust air through hole is horizontally provided on the serpentine drying pipe.

4. The bentonite additive drying hot air device according to claim 3, wherein the U-shaped slide bar comprises a horizontal end, sliding ends which are vertically arranged downwards are arranged at the front end and the rear end of the horizontal end, sliding grooves matched with the sliding ends are formed in the front side and the rear side of the top of the crushing bin, and the sliding ends slide in the sliding grooves;

the long screw is connected to the horizontal end in a threaded manner.

5. The bentonite additive drying hot air device according to claim 4, wherein a plurality of interval adjusting nuts are connected to the long screw in a threaded manner;

the upper end parts of the arc-shaped rods are respectively provided with a sliding part which is horizontally arranged, and the sliding parts are in sliding connection with the long screw rods;

the plurality of interval adjusting nuts are respectively extruded at the top and the bottom of the sliding part.

6. The bentonite additive drying hot air apparatus according to claim 5, wherein the arc surface of the arc rod is disposed toward the left.

7. The hot air device for drying bentonite additives according to claim 6, wherein a plurality of the crushed aggregates cones are distributed on the arc surface of the arc rod in an arc shape; the driving part comprises a screw rod which is connected with the front ends of the plurality of U-shaped slide bars in a threaded manner;

the screw rod is in threaded connection with the sliding end of the U-shaped sliding rod;

the left end of the screw rod is rotationally connected to the left groove wall of the chute;

the right end of the screw rod penetrates through the sliding groove, and a screw rod motor is arranged at the right end of the screw rod.

8. The bentonite additive drying hot air device according to claim 7, wherein the rear sides of the plurality of U-shaped slide bars are connected with guide rods in a sliding manner;

the guide rods penetrate through the sliding ends of the U-shaped sliding rods;

the left end and the right end of the guide rod are respectively and fixedly connected to the left groove wall and the right groove wall of the chute.

9. The bentonite additive drying hot air device according to claim 8, wherein the front and rear ends of the tops of the plurality of U-shaped slide bars are respectively provided with mounting plates;

the mounting plate is assembled and connected to the U-shaped slide bars through mounting bolts.