CN212120308U - Active carbon raw material crushing, conveying and caching system for recycling raw material dust - Google Patents

Abstract

An active carbon raw material crushing, conveying and caching system for recycling raw material dust comprises a crusher, a conveying belt, a temporary storage bin and a dust recycling device, wherein dust overflow preventing covers are mounted outside the crusher and the conveying belt, and the inlet end of the dust recycling device is communicated with the interior of the dust overflow preventing cover; through the conveyor belt who sets up, we can directly carry the raw materials after the breakage to the temporary storage storehouse in, the conveying efficiency has been improved, the human labor has been reduced, prevent the dust and spill over the cover through installing additional on the belt conveyor breaker, can effectually prevent that the dust from flying upward and scatter, thereby make the dust amasss the inside that the dust spills over the cover, at this moment, we can take away and collect the dust that flies upward in preventing that the dust spills over the cover through the dust recovery unit who sets up, the problem that the dust flies upward has not only been solved, and can recycle the dust recovery of collection, reduced and the waste of resource.

Description

Active carbon raw material crushing, conveying and caching system for recycling raw material dust

Technical Field

The utility model relates to an active carbon production facility technical field especially relates to a buffer memory system is carried in active carbon raw materials breakage of recycle raw materials dust.

Background

When the activated carbon is produced, raw materials for preparing the activated carbon are firstly crushed, then the crushed raw materials are conveyed to a temporary storage tank for temporary storage, and then the raw materials are conveyed to activated carbon activation equipment for further production. However, the method adopted at present is to discharge the crushed raw materials after the crushing by the crusher, then manually load the crushed raw materials onto the trolley, and then convey the crushed raw materials into the temporary storage tank, and this method is not only labor-consuming and inefficient, but also causes waste of raw materials because more raw materials are scattered on the conveying route.

Disclosure of Invention

In view of the above, there is a need for an activated carbon raw material crushing and conveying buffer system for recycling raw material dust.

The utility model provides a broken buffer memory system of carrying of active carbon raw materials of recycle raw materials dust, which comprises a crusher, conveyor belt, the storehouse of keeping in, dust recovery unit, conveyor belt's entry end is located the exit end below of breaker, conveyor belt's entry end is located the storehouse of keeping in directly over, the cover is overflowed to the dust of preventing all installing in breaker and conveyor belt's outside, prevent that the dust from overflowing the cover and wrap up breaker and conveyor belt completely in the inside that the cover was overflowed to the dust of preventing, dust recovery unit's entry end leads to and prevents that the dust spills over the inside intercommunication of cover, collect the recovery after the dust extraction that produces when being used for overflowing the dust of preventing to cover when carrying because the breaker.

Preferably, the dust recovery device comprises a dust collector, a dust remover, a dust collecting fan and a dust collecting main pipeline, wherein the dust collecting main pipeline is communicated with the interior of the dust overflow prevention cover, the inlet end of the dust collecting fan is communicated with the outlet end of the dust collecting main pipeline, the inlet end of the dust collector is communicated with the outlet end of the dust collecting fan through a pipeline, the outlet end of the dust collector is communicated with the dust remover through a pipeline, the dust collector comprises a shell, an air outlet buffer cavity is arranged on the left side of the outside of the shell, an air inlet buffer cavity is arranged on the right side of the outside of the shell, a partition plate is fixedly arranged below the inside of the shell and divides the inside of the shell into an upper cavity and a lower cavity, baffles are arranged in the upper cavity at intervals in a vertical staggered mode and divide the upper cavity into S-shaped channels, round holes for the, one end of the air inlet is communicated with the air inlet buffer cavity, and one end of the air outlet is communicated with the air outlet buffer cavity.

Preferably, the partition plate is provided with an electric gate valve for discharging dust accumulated in the upper cavity into the lower cavity.

Preferably, the top of the dust overflow prevention cover is provided with a dust collection pipeline, the inlet end of the dust collection pipeline is communicated with the upper part of the interior of the dust overflow prevention cover, and the outlet end of the dust collection pipeline is communicated with the dust collection main pipeline.

Preferably, the dust suction pipes are equidistantly distributed when the dust overflows the top of the cover.

Preferably, the temporary storage bin comprises a first temporary storage bin, a middle temporary storage bin and a second temporary storage bin, the first temporary storage bin, the middle temporary storage bin and the second temporary storage bin are sequentially arranged, a raw material flow dividing device is installed at the top of the first temporary storage bin, the middle temporary storage bin and the second temporary storage bin, the inlet end of the raw material flow dividing device is located under the outlet end of the conveying belt, and the outlet end of the raw material flow dividing device is respectively opposite to the inlet of the first temporary storage bin, the middle temporary storage bin and the inlet of the second temporary storage bin.

Preferably, the raw material shunting device comprises a middle blanking pipe, a first blanking pipe and a second blanking pipe, the middle blanking pipe is arranged under the outlet end of the conveying belt, the inlet end of the middle blanking pipe is right below the outlet end of the conveying belt, the outlet end of the middle blanking pipe is right below the inlet end of the middle buffering bin, the first blanking pipe is located on the right side of the middle blanking pipe, the inlet end of the first blanking pipe is communicated with the upper portion of the middle blanking pipe, the outlet end of the first blanking pipe is right above the inlet of the first buffering bin, the second blanking pipe is located on the left side of the middle blanking pipe, the inlet end of the second blanking pipe is communicated with the lower portion of the middle blanking pipe, and the outlet end of the second blanking pipe is right above the inlet of the second buffering bin.

Preferably, a first electric gate valve is installed on the upper portion of the middle discharging pipe and located below the inlet end of the first discharging pipe, and a second electric gate valve is installed on the lower portion of the middle discharging pipe and located below the inlet end of the second discharging pipe.

Preferably, the inlet end of the middle feeding pipe is provided with a funnel-shaped receiving port.

The utility model adopts the above technical scheme, its beneficial effect lies in: the utility model discloses an including breaker, conveyor belt, temporary storage storehouse, dust recovery unit, conveyor belt's entry end is located the exit end below of breaker, conveyor belt's entry end is located temporary storage storehouse directly over, breaker and conveyor belt's outside all is installed and is prevented the dust and spill over the cover, prevent that the dust spills over the cover and wrap up breaker and conveyor belt completely in the inside of preventing the dust and spill over the cover, the entry end of dust recovery unit leads to and prevents the inside intercommunication of dust spill over the cover, collect and retrieve the dust that produces when being used for carrying the breaker in preventing the dust spill over the cover inside after extracting; through the conveyor belt who sets up, we can directly carry the raw materials after the breakage to the temporary storage storehouse in, the conveying efficiency has been improved, the human labor has been reduced, prevent the dust and spill over the cover through installing additional on the belt conveyor breaker, can effectually prevent that the dust from flying upward and scatter, thereby make the dust amasss the inside that the dust spills over the cover, at this moment, we can take away and collect the dust that flies upward in preventing that the dust spills over the cover through the dust recovery unit who sets up, the problem that the dust flies upward has not only been solved, and can recycle the dust recovery of collection, reduced and the waste of resource.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

Fig. 2 is the structure schematic diagram of the dust fall device of the utility model.

Fig. 3 is a schematic structural view of the connection between the material distributing device and the temporary storage bin.

In the figure: the device comprises a crusher 01, a conveying belt 02, a dust recovery device 03, a dust remover 31, a shell 311, an air outlet buffer cavity 312, an air inlet buffer cavity 313, a partition 314, an electric gate valve 3141, a baffle 315, a heating pipe 316, a dust remover 32, a dust collection fan 33, a dust collection main pipeline 34, a temporary storage bin 04, a first buffer storage bin 41, an intermediate buffer storage bin 42, a second buffer storage bin 43, a dust overflow prevention cover 05, a dust collection pipeline 51, a raw material shunting device 06, an intermediate discharging pipe 61, a material receiving port 611, a first discharging pipe 62, a second discharging pipe 63, a first electric gate valve 64 and a second electric gate valve 65.

Detailed Description

Referring to fig. 1 to 3, an embodiment of the present invention provides an activated carbon raw material crushing and conveying buffer memory system for recycling raw material dust, including a crusher 01, a conveying belt 02, a temporary storage chamber 04, and a dust recycling device 03, wherein an inlet end of the conveying belt 02 is located below an outlet end of the crusher 01, an inlet end of the conveying belt 02 is located right above the temporary storage chamber 04, dust overflow prevention covers 05 are installed outside the crusher 01 and the conveying belt 02, the crusher 01 and the conveying belt 02 are completely wrapped inside the dust overflow prevention covers 05 by the dust overflow prevention covers 05, an inlet end of the dust recycling device 03 is communicated with the inside of the dust overflow prevention covers 05, so as to extract dust generated in the dust overflow prevention covers 05 during conveying by the crusher 01 and collect and recycle the extracted dust; through the conveyor belt 02 that sets up, we can directly carry the raw materials after the breakage to in the temporary storage storehouse 04, the conveying efficiency is improved, the human labor is reduced, it overflows cover 05 to prevent the dust through installing additional on conveyor belt 02 machine breaker 01, can effectually prevent that the dust from flying upward and scatter, thereby make the dust amasss the inside that the dust spills over cover 05, at this moment, we are through the dust recovery unit 03 that sets up, can take away and collect the dust that flies upward in preventing that the dust spills over cover 05, the problem that the dust flies upward has not only been solved, and can recycle the dust of collecting, reduced and the waste of resource.

The dust recovery device 03 comprises a dust collector 31, a dust remover 32, a dust collecting fan 33 and a dust collecting main pipeline 34, wherein the dust collecting main pipeline 34 is communicated with the interior of the dust overflow prevention cover 05, the inlet end of the dust collecting fan 33 is communicated with the outlet end of the dust collecting main pipeline 34, the inlet end of the dust collector 31 is communicated with the outlet end of the dust collecting fan 33 through a pipeline, the outlet end of the dust collector 31 is communicated with the dust remover 32 through a pipeline, the dust collector 31 comprises a shell 311, an air outlet buffer cavity 312 is arranged on the left side of the outside of the shell 311, an air inlet buffer cavity 313 is arranged on the right side of the outside of the shell 311, a partition 314 is fixedly arranged below the inside of the shell 311, the partition 314 partitions the inside of the shell 311 into an upper cavity and a lower cavity, and an electric gate valve 3141 is arranged; baffles 315 are arranged in the upper cavity in an up-and-down staggered equidistant manner, the baffles 315 divide the upper cavity into S-shaped channels, the stroke of high-temperature dust can be increased, thereby being beneficial to settling and cooling the high-temperature dust, round holes for the heating pipes 316 to pass through are arranged on the baffles 315, the heating pipes 316 are arranged in the upper cavity along the horizontal direction and pass through the round holes on the baffles 315, one end of air inlet is communicated with the air inlet buffer cavity 313, one end of air outlet is communicated with the air outlet buffer cavity 312, hot air is introduced from the inlet end of the air inlet buffer cavity 313, so that the hot air firstly enters the air inlet buffer cavity 313 and then enters the heating pipes 316, thereby the hot air and the dust entering the dust remover 31 can carry out heat exchange, thereby carrying out certain temperature rise on the dust, keeping the dust dry, avoiding the caking phenomenon, and the air after the heat exchange enters the air outlet buffer cavity 312, and exits through the outlet end of the exit buffer chamber 312.

The top of the dust overflow preventing cover 05 is provided with a dust suction pipeline 51, the inlet end of the dust suction pipeline 51 is communicated with the upper part of the inside of the dust overflow preventing cover 05, and the outlet end of the dust suction pipeline 51 is communicated with the dust collecting main pipeline 34. The dust suction pipes 51 are equidistantly distributed when dust overflows the top of the dust overflow prevention cap 05.

Temporary storage storehouse 04 includes first buffer storehouse 41, middle buffer storehouse 42, second buffer storehouse 43, first buffer storehouse 41, middle buffer storehouse 42, second buffer storehouse 43 sets gradually, and install raw materials diverging device 06 at first buffer storehouse 41, middle buffer storehouse 42, the top of second buffer storehouse 43, the entry end of raw materials diverging device 06 is located conveyor belt 02 exit end under, the exit end of raw materials diverging device 06 is just to first buffer storehouse 41 respectively, middle buffer storehouse 42, the entry of second buffer storehouse 43.

The raw material shunting device 06 comprises a middle blanking pipe 61, a first blanking pipe 62 and a second blanking pipe 63, wherein the middle blanking pipe 61 is arranged right below the outlet end of the conveying belt 02, the inlet end of the middle blanking pipe 61 is right opposite to the outlet end of the conveying belt 02, the outlet end of the middle blanking pipe 61 is right opposite to the inlet of the middle buffer storage bin 42, and the inlet end of the middle blanking pipe 61 is provided with a funnel-shaped material receiving port 611, so that raw materials on the conveying belt 02 can fall into the middle blanking pipe 61 better, and the raw materials are prevented from scattering out; the first blanking pipe 62 is located on the right side of the middle blanking pipe 61, the inlet end of the first blanking pipe 62 is communicated with the upper portion of the middle blanking pipe 61, the outlet end of the first blanking pipe 62 faces the inlet of the first buffer storage bin 41, the second blanking pipe 63 is located on the left side of the middle blanking pipe 61, the inlet end of the second blanking pipe 63 is communicated with the lower portion of the middle blanking pipe 61, and the outlet end of the second blanking pipe 63 faces the inlet of the second buffer storage bin 43. A first electric gate valve 64 is installed on the upper portion of the middle blanking pipe 61, the first electric gate valve 64 is located below the inlet end of the first blanking pipe 62, a second electric gate valve 65 is installed on the lower portion of the middle blanking pipe 61, and the second electric gate valve 65 is located below the inlet end of the second blanking pipe 63. After the broken raw materials are conveyed by the conveying belt 02, the opening and closing states of the first electric gate valve 64 and the second electric gate valve 65 are controlled respectively, when the first electric gate valve 64 is closed, the broken raw materials enter the first buffer storage bin 41, the first electric gate valve 64 is opened, when the second electric gate valve 65 is closed, the broken raw materials enter the second buffer storage bin 43, when the first electric gate valve 64 and the second electric gate valve 65 are opened simultaneously, the broken raw materials enter the middle buffer storage bin 42, and therefore the broken raw materials can be distributed to the first buffer storage bin 41, the middle buffer storage bin 42 and the second buffer storage bin 43 respectively according to requirements.

While the invention has been described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention.

Claims (9)

1. The utility model provides a broken buffer memory system that carries of active carbon raw materials of recycle raw materials dust which characterized in that: including the breaker, conveyor belt, the temporary storage storehouse, dust recovery unit, conveyor belt's entry end is located the exit end below of breaker, conveyor belt's entry end is located the temporary storage storehouse directly over, the dust overflow prevention cover is all installed to breaker and conveyor belt's outside, the dust overflow prevention cover wraps up breaker and conveyor belt completely in the inside that the dust overflows the cover, dust recovery unit's entry end leads to and prevents the inside intercommunication that the dust spills over the cover, collect the recovery after the dust extraction that produces when will prevent the dust and overflow the cover inside because the breaker carries.

2. The activated carbon raw material crushing and conveying buffer system for recycling raw material dust according to claim 1, characterized in that: the dust recovery device comprises a dust collector, a dust remover, a dust collecting fan and a dust collecting main pipeline, wherein the dust collecting main pipeline is communicated with a dust overflow prevention cover, the inlet end of the dust collecting fan is communicated with the outlet end of the dust collecting main pipeline, the inlet end of the dust remover is communicated with the outlet end of the dust collecting fan through a pipeline, the outlet end of the dust remover is communicated with the dust remover through a pipeline, the dust remover comprises a shell, an air outlet buffer cavity is arranged on the left side outside the shell, an air inlet buffer cavity is arranged on the right side outside the shell, a partition plate is fixedly arranged below the inside of the shell and divides the inside of the shell into an upper cavity and a lower cavity, baffles are arranged in the upper cavity at intervals which are staggered up and down and divide the upper cavity into S-shaped channels, round holes for passing heating pipes are formed in the, one end of the air inlet is communicated with the air inlet buffer cavity, and one end of the air outlet is communicated with the air outlet buffer cavity.

3. The activated carbon raw material crushing and conveying buffer system for recycling raw material dust according to claim 2, characterized in that: an electric gate valve is mounted on the partition plate and used for discharging dust accumulated in the upper cavity into the lower cavity.

4. The activated carbon raw material crushing and conveying buffer system for recycling raw material dust according to claim 1, characterized in that: prevent that the dust spills over the top of cover and install dust absorption pipeline, dust absorption pipeline's entry end and the inside top intercommunication that the dust spills over the cover, dust absorption pipeline's exit end and collection dirt main pipe intercommunication.

5. The activated carbon raw material crushing and conveying buffer system for recycling raw material dust according to claim 4, wherein: the dust absorption pipeline is equidistantly distributed when the dust is prevented from overflowing the top of the cover.

6. The activated carbon raw material crushing and conveying buffer system for recycling raw material dust according to claim 1, characterized in that: the temporary storage bin comprises a first temporary storage bin, a middle temporary storage bin and a second temporary storage bin, the first temporary storage bin, the middle temporary storage bin and the second temporary storage bin are sequentially arranged, a raw material flow dividing device is installed at the top of the first temporary storage bin, the middle temporary storage bin and the second temporary storage bin, the inlet end of the raw material flow dividing device is located under the outlet end of the conveying belt, and the outlet end of the raw material flow dividing device is respectively opposite to the inlet of the first temporary storage bin, the middle temporary storage bin and the second temporary storage bin.

7. The system for crushing, conveying and caching activated carbon raw material for recycling raw material dust as claimed in claim 6, wherein: the raw material shunting device comprises an intermediate blanking pipe, a first blanking pipe and a second blanking pipe, wherein the intermediate blanking pipe is arranged under the outlet end of the conveying belt, the inlet end of the intermediate blanking pipe is just under the outlet end of the conveying belt, the outlet end of the intermediate blanking pipe is just under the inlet of the intermediate buffering bin, the first blanking pipe is positioned on the right side of the intermediate blanking pipe, the inlet end of the first blanking pipe is communicated with the upper part of the intermediate blanking pipe, the outlet end of the first blanking pipe is just over against the inlet of the first buffering bin, the second blanking pipe is positioned on the left side of the intermediate blanking pipe, the inlet end of the second blanking pipe is communicated with the lower part of the intermediate blanking pipe, and the outlet end of the second blanking pipe is just over against the inlet of the second buffering bin.

8. The system for crushing, conveying and caching activated carbon raw material for recycling raw material dust according to claim 7, wherein the system comprises: a first electric gate valve is installed on the upper portion of the middle discharging pipe and located below the inlet end of the first discharging pipe, and a second electric gate valve is installed on the lower portion of the middle discharging pipe and located below the inlet end of the second discharging pipe.

9. The system for crushing, conveying and caching activated carbon raw material for recycling raw material dust according to claim 7, wherein the system comprises: the inlet end of the middle blanking pipe is provided with a funnel-shaped material receiving port.

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