CN219540227U - Quantitative mixing and granulating production line for fly ash - Google Patents

Abstract

The quantitative fly ash mixing and granulating production line comprises a raw material bin; the raw material bin is connected with a mixed parasitic device through a first conveying mechanism, and the mixed parasitic device is provided with a plurality of weighing feed inlets; a plurality of proportioning bins; the plurality of proportioning bins are correspondingly connected with the plurality of weighing feed inlets for transmission; a mixing mechanism; the mixing hopper is connected with the mixing mechanism through a second conveying mechanism, and the mixing mechanism is provided with a laminated double-layer mixing cavity; a granulator; the lower layer mixing cavity of the mixing mechanism is connected with the granulator through a third conveying mechanism. It can be seen from the above description that through multistage conveying, raw materials and ingredients are accurately added in the conveying process, so that higher proportioning degree is guaranteed, meanwhile, the raw materials and ingredients are fully mixed in a mixing mechanism, higher application value is achieved, and granulation quality is improved.

Description

Quantitative mixing and granulating production line for fly ash

Technical field:

the utility model relates to the technical field of fly ash, in particular to a fly ash quantitative mixing granulation production line.

The background technology is as follows:

the flyash is one kind of building material for building engineering, and is used in building engineering together with other building material, and is used in preparing light aggregate concrete.

However, in the fly ash granulation process, part of auxiliary materials are required to be added for full mixing and then granulation is carried out, the environment in the whole working condition is easy to pollute, meanwhile, the purpose of accurate addition is not achieved, in addition, the stirring requirement is higher in the fly ash granulation process, and the full mixing cannot be realized by a single stirring mode, so that the granulation standard is not uniform.

The utility model comprises the following steps:

in view of the above, the utility model provides a fly ash quantitative mixing granulation production line, which adopts closed type multistage transmission, ensures more efficient mixing and has higher application value.

The quantitative fly ash mixing and granulating production line comprises a raw material bin; the raw material bin is connected with a mixed mailer through a first conveying mechanism, and the mixed mailer is provided with a plurality of weighing feed inlets;

a plurality of proportioning bins; the plurality of proportioning bins are connected with the plurality of weighing feed inlets for transmission;

a mixing mechanism; the mixing hopper is connected with the mixing mechanism through a second conveying mechanism, and the mixing mechanism is provided with a stacked double-layer mixing cavity;

a granulator; the lower layer mixing cavity of the mixing mechanism is connected with the granulator through a third conveying mechanism; wherein, the liquid crystal display device comprises a liquid crystal display device,

the upper layer mixing cavity of mixing mechanism rotates along vertical direction circumference and is connected with first rabbling mechanism, the lower floor mixing cavity of mixing mechanism rotates along horizontal transverse direction circumference and is connected with second rabbling mechanism, just first rabbling mechanism with second rabbling mechanism connects at same drive arrangement, and upper layer mixing cavity with be provided with electronic baffle device between the lower floor mixing cavity.

Preferably, the former feed bin is connected with the support, the top of support is equipped with and is used for covering the dust cover of establishing former feed bin.

Preferably, a first cover plate is arranged at the top of the mixing mailer, and the discharge end of the first conveying mechanism penetrates through the first cover plate and extends to the inside of the mixing mailer.

Preferably, a conveying mechanism is horizontally arranged at the bottom of the mixed mailer, and the conveying mechanism is connected with the second conveying mechanism.

Preferably, a second cover plate is arranged at the top of the mixing mechanism, and the discharge end of the second conveying mechanism penetrates through the second cover plate and extends to the upper mixing cavity.

Preferably, the first stirring mechanism comprises a first stirring shaft which is vertically arranged, and a plurality of first stirring blades which are positioned in the upper layer mixing cavity are oppositely arranged on the first stirring shaft;

the first stirring shaft penetrates through the electric partition plate device and then extends into the lower layer mixing cavity to be connected with the driving device.

Preferably, the second stirring mechanism comprises second stirring shafts which are oppositely arranged at two sides of the driving device; each second stirring shaft is provided with a plurality of second stirring blades, and each second stirring shaft is rotationally connected with the lower layer mixing cavity.

Preferably, the driving device includes: the gear box is arranged in the lower layer mixing cavity; the inside of the gear box is rotationally connected with a first bevel gear, and a plurality of second bevel gears are connected with the first bevel gear in a circumferential meshing manner;

the first stirring shaft and the two second stirring shafts are fixedly connected with the corresponding second bevel gears;

the driving device further comprises a stirring motor, and an output shaft of the stirring motor is connected with a corresponding second bevel gear in a meshed mode to drive the first bevel gear to rotate.

Preferably, the electric spacer device includes: the baffle that the level set up, offered a plurality of weeping holes on the baffle, and all articulated be connected with electromagnetic shield on arbitrary weeping hole.

Preferably, a third cover plate is arranged at the top of the granulator, and the discharge end of the third conveying mechanism penetrates through the third cover plate and then extends into the granulator.

According to the utility model, through multistage conveying, closed conveying is performed in the conveying process, the working condition environment quality is improved, the raw materials and the ingredients are accurately added in the conveying process, the higher proportioning degree is ensured, meanwhile, the materials are fully mixed in the mixing mechanism, the high application value is realized, and the granulating quality is improved.

Description of the drawings:

FIG. 1 is a schematic structural diagram of a quantitative fly ash mixing and granulating production line provided by the utility model;

FIG. 2 is a top view of the fly ash quantitative mixing granulation production line provided by the utility model;

FIG. 3 is a schematic structural view of the mixing mechanism provided by the utility model;

fig. 4 is a schematic structural view of the gear box provided by the utility model.

In the figure:

the device comprises a bracket-1, a raw material bin-2, a first conveying mechanism-3, a mixing hopper-4, a weighing feed inlet-5, a first cover plate-6, a conveying mechanism-7, a second conveying mechanism-8, a mixing mechanism-9, a gear box-91, a first bevel gear-911, a second bevel gear-912, a partition plate-92, an electromagnetic baffle-93, a first stirring shaft-94, a first stirring blade-95, a second stirring shaft-96, a second stirring blade-97, an inclined surface-98, a stirring motor-99, a second cover plate-10, a third conveying mechanism-11, a granulator-12, a third cover plate-13 and a proportioning bin-14.

The specific embodiment is as follows:

referring to fig. 1 together, fig. 1 is a schematic structural diagram of a quantitative fly ash mixing granulation production line provided by the utility model; the fly ash quantitative mixing granulation production line comprises a raw material bin 2; the raw material bin 2 is used for bearing the fly ash, the capacity of the raw material bin 2 is about 50 cubic meters, a bin body or a tank body is adopted, and the fly ash is stored in the raw material bin 2 in a conveying mode. When former feed bin 2 adopts the storehouse body to bear, former feed bin 2 is connected with support 1, and the top of support 1 is equipped with the dust cover that is used for covering former feed bin 2. Thereby effectively inhibiting fly of the fly ash in the processing process and protecting the working condition environment from being polluted.

In the fly ash granulation process, auxiliary ingredients are required to be mixed, and for this purpose, the raw material bin 2 is connected with a mixing hopper 4 through a first conveying mechanism 3, and the mixing hopper 4 is provided with a plurality of weighing feed inlets 5. In the embodiment of the utility model, the weighing feed inlets 5 are four opposite, and the weighing feed inlets 5 are used for preliminary mixing in the mixing mailer 4 after weighing when ingredients are added. As shown in connection with fig. 2, four proportioning bins 14 are also included; the four proportioning bins 14 are in one-to-one correspondence connection and transmission with the four weighing feed inlets 5; the proportioning bin 14 is transmitted by a conveyor belt or a screw conveyor, and is weighed at the weighing feed inlet 5, and after the proportioning is uniform, the weighing feed inlet 5 is opened to enable the proportioning to enter the mixing hopper 4. At the same time, a first cover plate 6 is arranged at the top of the mixing mailer 4, and the discharge end of the first conveying mechanism 3 extends to the inside of the mixing mailer 4 through the first cover plate 6. The first conveying mechanism 3 adopts a screw conveyor which is obliquely arranged, and the discharge end can pass through the first cover plate 6, so that the pollution to the working condition environment in the mixing process is avoided.

The mixing hopper 4 conveys the fly ash and the ingredients after the proportioning is completed. The conveying end of the mixing hopper 4 is provided with a mixing mechanism 9, and the mixing mechanism 9 is used for fully mixing the fly ash and the ingredients. The mixing hopper 4 is connected with a mixing mechanism 9 through a second conveying mechanism 8, and the mixing mechanism 9 is provided with a laminated double-layer mixing cavity; and, a conveying mechanism 7 is horizontally arranged at the bottom of the mixing mailer 4, and the conveying mechanism 7 is connected with a second conveying mechanism 8. The conveying mechanism 7 adopts a screw conveyor, and the raw materials and the ingredients are primarily mixed in the conveying process and enter the mixing mechanism for remixing through the second conveying mechanism 8.

The second conveying mechanism 8 adopts screw conveyer, and the top of compounding mechanism 9 is equipped with second apron 10, and the discharge end of second conveying mechanism 8 runs through second apron 10 and extends to upper strata compounding chamber. Therefore, the purpose of preventing dust diffusion is achieved in the process of mixing and stirring materials.

Referring to fig. 3, in order to ensure better stirring and mixing effect, a double-layer mixing cavity is adopted for mixing and stirring, a first stirring mechanism is rotationally connected to an upper layer mixing cavity of a mixing mechanism 9 along the vertical direction in the circumferential direction, a second stirring mechanism is rotationally connected to a lower layer mixing cavity of the mixing mechanism 9 along the horizontal and transverse direction in the circumferential direction, the first stirring mechanism and the second stirring mechanism are connected to the same driving device, and an electric baffle 92 device is arranged between the upper layer mixing cavity and the lower layer mixing cavity.

Specifically, the first stirring mechanism comprises a first stirring shaft 94 which is vertically arranged, and a plurality of first stirring blades 95 which are positioned in the upper layer mixing cavity are oppositely arranged on the first stirring shaft 94; the first stirring shaft 94 penetrates through the electric partition plate 92, extends into the lower mixing cavity and is connected with the driving device. Thereby the first stirring mechanism performs circumferential mixing stirring in the upper mixing cavity.

The second stirring mechanism comprises second stirring shafts 96 which are oppositely arranged at two sides of the driving device; each second stirring shaft 96 is provided with a plurality of second stirring blades 97, and each second stirring shaft 96 is rotatably connected to the lower layer mixing cavity. So that the second stirring mechanism performs mixing stirring in different directions in the lower layer mixing cavity.

As shown in connection with fig. 4, the driving device includes: a gear box 91 arranged in the lower mixing cavity; a first bevel gear 911 is rotatably connected to the inside of the gear box 91, and a plurality of second bevel gears 912 are engaged and connected to the first bevel gear 911 in the circumferential direction; the first stirring shaft 94 and the two second stirring shafts 96 are fixedly connected with corresponding second bevel gears 912;

the driving device further comprises a stirring motor 99, and an output shaft of the stirring motor 99 is connected with a corresponding second bevel gear 912 to drive the first bevel gear 911 to rotate. Therefore, after the stirring motor 99 is turned on, the second bevel gear 912 at the bottom is driven to rotate, so that the first bevel gear rotates, and under the action of the transmission mode, the first bevel gear 911 drives the other three second bevel gears 912 to transfer, so as to form different rotation modes, and the first stirring shaft 94 and the two second stirring shafts 96 rotate, so that the aim of better stirring and mixing is achieved.

In addition, as shown in connection with fig. 1, the electric spacer 92 device includes: the baffle 92 that the level set up, a plurality of weeping holes have been seted up on the baffle 92, and all articulate on arbitrary weeping hole and be connected with electromagnetic shield 93. After the first stirring mechanism stirs and mixes for a certain period of time, through closing the electromagnetism, electromagnetic shield 93 opens under the oppression of material gravity, drops to the lower floor and mixes in the middle of the chamber and continue stirring and mix, guarantees higher mixing effect to set up inclined plane 98 in the bottom of compounding mechanism 9, thereby make third transport mechanism 11 be convenient for carry out the material completely.

Meanwhile, the terminal of the production line is a granulator 12, and a lower layer mixing cavity of the mixing mechanism 9 is connected with the granulator 12 through a third conveying mechanism 11; the third conveying mechanism 11 adopts a screw conveyor, a third cover plate 13 is assembled at the top of the granulator 12, and the discharge end of the third conveying mechanism 11 penetrates through the third cover plate 13 and then extends into the granulator 12. The aim of dust suppression of the whole production line is guaranteed, and the stirring and mixing standard is higher.

According to the utility model, through multistage conveying, closed conveying is performed in the conveying process, the working condition environment quality is improved, the raw materials and the ingredients are accurately added in the conveying process, the higher proportioning degree is ensured, meanwhile, the materials are fully mixed in the mixing mechanism 9, the high application value is realized, and the granulating quality is improved.

Those of ordinary skill in the art will appreciate that: the discussion of any of the embodiments above is merely exemplary and is not intended to suggest that the scope of the disclosure, including the claims, is limited to these examples; the technical features of the above embodiments or in the different embodiments may also be combined under the idea of the present disclosure, the steps may be implemented in any order, and there are many other variations of the different aspects of one or more embodiments of the present description as above, which are not provided in details for the sake of brevity.

Additionally, well-known connections to other components may or may not be shown in the drawings provided to simplify the description and discussion, and so as not to obscure one or more embodiments of the present description. Furthermore, the system may be shown in block diagram form in order to avoid obscuring the embodiment(s) of the present description, and also in view of the fact that specifics with respect to implementation of such block diagram system are highly dependent upon the platform on which the embodiment(s) of the present description is to be implemented (i.e., such specifics should be well within purview of one skilled in the art). Where specific details are set forth in order to describe example embodiments of the disclosure, it should be apparent to one skilled in the art that one or more embodiments of the disclosure can be practiced without, or with variation of, these specific details. Accordingly, the description is to be regarded as illustrative in nature and not as restrictive.

While the present disclosure has been described in conjunction with specific embodiments thereof, many alternatives, modifications, and variations of those embodiments will be apparent to those skilled in the art in light of the foregoing description.

The present disclosure is intended to embrace all such alternatives, modifications and variances which fall within the broad scope of the appended claims. Any omissions, modifications, equivalents, improvements, and the like, which are within the spirit and principles of the one or more embodiments of the disclosure, are therefore intended to be included within the scope of the disclosure.

Claims (10)

1. The utility model provides a fly ash ration mixing granulation production line which characterized in that includes:

a raw material bin; the raw material bin is connected with a mixed mailer through a first conveying mechanism, and the mixed mailer is provided with a plurality of weighing feed inlets;

a plurality of proportioning bins; the plurality of proportioning bins are correspondingly connected with the plurality of weighing feed inlets for transmission;

a mixing mechanism; the mixing hopper is connected with the mixing mechanism through a second conveying mechanism, and the mixing mechanism is provided with a stacked double-layer mixing cavity;

a granulator; the lower layer mixing cavity of the mixing mechanism is connected with the granulator through a third conveying mechanism; wherein, the liquid crystal display device comprises a liquid crystal display device,

the upper layer mixing cavity of mixing mechanism rotates along vertical direction circumference and is connected with first rabbling mechanism, the lower floor mixing cavity of mixing mechanism rotates along horizontal transverse direction circumference and is connected with second rabbling mechanism, just first rabbling mechanism with second rabbling mechanism connects at same drive arrangement, and upper layer mixing cavity with be provided with electronic baffle device between the lower floor mixing cavity.

2. The fly ash quantitative mixing granulation production line according to claim 1, wherein the raw material bin is connected with a bracket, and a dust cover for covering the raw material bin is assembled on the top of the bracket.

3. The fly ash quantitative mixing granulation production line according to claim 1, wherein a first cover plate is arranged at the top of the mixing hopper, and a discharge end of the first conveying mechanism penetrates through the first cover plate and extends into the mixing hopper.

4. A fly ash quantitative mixing granulation production line according to claim 3, wherein the bottom of the mixing hopper is horizontally provided with a conveying mechanism, and the conveying mechanism is connected with the second conveying mechanism.

5. The fly ash quantitative mixing granulation production line according to claim 1, wherein a second cover plate is arranged at the top of the mixing mechanism, and a discharge end of the second conveying mechanism penetrates through the second cover plate and extends to the upper mixing cavity.

6. The fly ash quantitative mixing granulation production line according to claim 5, wherein the first stirring mechanism comprises a first stirring shaft which is vertically arranged, and a plurality of first stirring blades which are positioned in the upper layer mixing cavity are oppositely arranged on the first stirring shaft;

the first stirring shaft penetrates through the electric partition plate device and then extends into the lower layer mixing cavity to be connected with the driving device.

7. The fly ash quantitative mixing granulation production line according to claim 6, wherein the second stirring mechanism comprises second stirring shafts oppositely arranged at two sides of the driving device; each second stirring shaft is provided with a plurality of second stirring blades, and each second stirring shaft is rotationally connected with the lower layer mixing cavity.

8. The fly ash quantitative mixing granulation production line according to claim 7, wherein the driving device comprises: the gear box is arranged in the lower layer mixing cavity; the inside of the gear box is rotationally connected with a first bevel gear, and a plurality of second bevel gears are connected with the first bevel gear in a circumferential meshing manner;

the first stirring shaft and the two second stirring shafts are fixedly connected with the corresponding second bevel gears;

the driving device further comprises a stirring motor, and an output shaft of the stirring motor is connected with a corresponding second bevel gear in a meshed mode to drive the first bevel gear to rotate.

9. The fly ash quantitative mixing granulation line according to claim 1, wherein the electric separator device comprises: the baffle that the level set up, offered a plurality of weeping holes on the baffle, and all articulated be connected with electromagnetic shield on arbitrary weeping hole.

10. The fly ash quantitative mixing granulation production line according to claim 1, wherein a third cover plate is arranged at the top of the granulator, and the discharge end of the third conveying mechanism penetrates through the third cover plate and then extends into the granulator.