CN217330496U - Drying device with powder separation for activated carbon production - Google Patents

Abstract

The utility model relates to an active carbon technical field, and a drying device with powder separation is used in active carbon production is disclosed, including collecting the mechanism, the inside of collecting the mechanism is provided with stoving mechanism, it includes the box to collect the mechanism, equal fixedly connected with swash plate on two opposite faces of the inside wall of box, the interior bottom of box is installed and is connect the hopper, connect sliding connection between hopper and the pull groove, stoving mechanism includes the net drum, the equal fixedly connected with bull stick in both ends of net drum, the one end of bull stick is provided with servo motor, install semicircle net door on the lateral wall of net drum, a plurality of blend stop of fixedly connected with on the inside wall of net drum, the top of net drum is provided with hot-blast plate. This active carbon production is with drying device who has powder separation possesses stoving, separation powder and goes on simultaneously, and advantages such as machining efficiency height have solved current drying device and have lacked the function of drying the separation powder simultaneously with columnar activated carbon, lead to the problem that machining efficiency is low.

Description

Drying device with powder separation for active carbon production

Technical Field

The utility model relates to an active carbon technical field specifically is an active carbon production is with drying device who has powder separation.

Background

The active carbon is prepared by refining high-quality coal, sawdust, fruit shell, coconut shell and other materials by advanced process equipment. The production process of the activated carbon is roughly divided into: charring → cooling → activating → washing. The shape of the finished product produced by the activated carbon is roughly divided into: granular, columnar, powdery, etc.

Activated carbon often needs to be dried after being made into a columnar shape so as to be stored, however, in the drying process, partial carbon powder still remains on the surface of the columnar activated carbon, and the existing drying device lacks the function of drying and separating the powder from the columnar activated carbon at the same time, so that the processing efficiency is low, and therefore, a drying device for separating the powder for activated carbon production is needed urgently.

SUMMERY OF THE UTILITY MODEL

Technical problem to be solved

Not enough to prior art, the utility model provides an active carbon production is with drying device who has the powder separation possesses stoving, separates the powder and goes on simultaneously, and advantages such as machining efficiency height have solved current drying device and have lacked the function of drying simultaneously and separating the powder with columnar active carbon, lead to the problem that machining efficiency is low.

(II) technical scheme

In order to achieve the above object, the utility model provides a following technical scheme: a drying device with powder separation for activated carbon production comprises a collecting mechanism, wherein a drying mechanism is arranged in the collecting mechanism;

the collecting mechanism comprises a box body, inclined plates are fixedly connected to two opposite surfaces of the inner side wall of the box body, a material receiving hopper is arranged at the inner bottom of the box body, a drawing groove is formed in the position, close to the bottom, of the outer side wall of the box body, and the material receiving hopper is connected with the drawing groove in a sliding mode;

the drying mechanism comprises a grid cylinder, rotating rods are fixedly connected to the two ends of the grid cylinder, a servo motor is arranged at one end of each rotating rod, a semicircular grid door is installed on the outer side wall of the grid cylinder, a plurality of blocking strips are fixedly connected to the inner side wall of the grid cylinder, and a hot air plate is arranged at the top of the grid cylinder.

Preferably, the receiving hopper comprises a hopper body, a separation net is fixedly connected to the inner side wall of the hopper body close to the middle position, and an ash receiving hopper is installed at the bottom of the separation net.

Preferably, the outer side wall of the bucket body is fixedly connected with a handle, and the bucket body is arranged at the bottoms of the two inclined plates.

The bucket body is pulled through the handle, so that the activated carbon columns and the activated carbon powder in the bucket body can be taken out conveniently and quickly.

Preferably, two ends of the rotating rods are movably connected with two opposite surfaces of the inner side wall of the box body respectively, and one of the rotating rods penetrates through the outer side wall of the box body, extends to the outside of the box body and is fixedly connected with the output end of the servo motor in a coaxial mode.

Fixedly connected with backup pad on the lateral wall of box, servo motor installs in the top of backup pad, and servo motor inner line connects for prior art, no longer gives unnecessary details here.

Preferably, one side of the semicircular grid door is hinged with the outer side wall of the grid cylinder, and the outer side wall of the grid cylinder is provided with a feeding port corresponding to the semicircular grid door.

The semicircle net door is half of net drum diameter, opens semicircle net door after, the inside active carbon post of net drum can unimpededly flow out the pan feeding mouth, can not cause to block to be difficult to the whereabouts.

Preferably, the hot air plate comprises a box top plate, an air outlet groove is fixedly connected to the bottom of the box top plate, an air conveying pipe is arranged on the outer side wall of the box top plate, the air conveying pipe penetrates through the box top plate and is communicated with the air outlet groove, and an air heater is arranged at the other end of the air conveying pipe.

The air heater internal line connects for prior art, no longer gives unnecessary details here, starts the air heater, and the air heater will be hot-blast to send out wind groove department through defeated tuber pipe, and the hot-blast blowing of air groove department is to the net drum to dry to the inside active carbon post of net drum.

Preferably, the box top plate is matched with the top of the box body, and the outer side wall of the box top plate is provided with a plurality of exhaust holes.

A large amount of water vapor can be generated in the process of drying the activated carbon columns, and the water vapor is upwards exhausted through the exhaust holes, so that the drying speed of the activated carbon columns is accelerated.

Compared with the prior art, the utility model provides an active carbon production is with drying device who has powder separation possesses following beneficial effect:

1. this active carbon production is with drying device who has powder separation, through switching semicircle net door, put into the net drum with the active carbon post of not dry treatment in, start servo motor, servo motor drives the net drum and rotates, open the hot-blast board, the hot-blast board blows hot-blast to the net drum, dry the active carbon post in the net drum, the dry powder that produces during this period can fall to two through the space on net drum surface and connect the hopper, two powder that connect on the hopper falls into on the hopper that connects of below through the interval between the two through the blowing of top hot-blast board, connect the hopper to catch the powder and separate, thereby reach the effect of drying and powder separation going on simultaneously, and the production efficiency is improved.

2. This active carbon production is with drying device who has powder separation, the net aperture through separating the net is less than the diameter of active carbon post, and after the active carbon cylinder was dried and is accomplished, open semicircle net door, the active carbon post falls down and falls into on the separating the net through the pan feeding mouth, takes out the bucket body, with the active carbon post take out can, convenient and fast.

Drawings

FIG. 1 is a schematic view of the three-dimensional structure of the present invention;

FIG. 2 is a schematic view of the three-dimensional unfolding structure of the present invention;

FIG. 3 is a schematic view of the sectional structure of the main viewing surface of the present invention;

fig. 4 is a schematic view of the cross-sectional side view of the present invention.

Wherein: 1. a collection mechanism; 101. a box body; 102. a sloping plate; 103. a receiving hopper; 1031. a bucket body; 1032. a separation net; 1033. an ash receiving hopper; 1034. a handle; 104. drawing the groove; 2. a drying mechanism; 201. a mesh cylinder; 202. a rotating rod; 203. a servo motor; 204. a semicircular grid door; 205. blocking strips; 206. a hot blast plate; 2061. a box top plate; 2062. an air outlet groove; 2063. a wind delivery pipe; 2064. a hot air blower; 2065. an exhaust hole; 207. and a feeding port.

Detailed Description

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

Referring to fig. 1-4, a drying device for active carbon production with powder separation comprises a collecting mechanism 1, wherein a drying mechanism 2 is arranged inside the collecting mechanism 1;

the collecting mechanism 1 comprises a box body 101, inclined plates 102 are fixedly connected to two opposite surfaces of the inner side wall of the box body 101, a material receiving hopper 103 is arranged at the inner bottom of the box body 101, a drawing groove 104 is formed in the position, close to the bottom, of the outer side wall of the box body 101, and the material receiving hopper 103 is connected with the drawing groove 104 in a sliding mode;

drying mechanism 2 includes net drum 201, and the equal fixedly connected with bull stick 202 in both ends of net drum 201, and the one end of bull stick 202 is provided with servo motor 203, installs semicircle net door 204 on the lateral wall of net drum 201, and fixedly connected with a plurality of blend stop 205 on the inside wall of net drum 201, the top of net drum 201 is provided with hot-blast plate 206.

Through the technical scheme, open and close semicircle net check door 204, put into net drum 201 with the activated carbon post of not dry processing, start servo motor 203, servo motor 203 drives net drum 201 and rotates, blend stop 205 separates each activated carbon post on the net drum 201 inside wall, thereby make the dust fall more easily, open hot-blast board 206, hot-blast board 206 blows hot-blast to net drum 201, dry the activated carbon post in net drum 201, the dry powder that produces during this period can fall on two connect hoppers 103 through the space on net drum 201 surface, two powder that connect on the hopper 103 fall into on the hopper 103 that connects of below through the interval between the two through the blowing of top hot-blast board 206, connect hopper 103 to catch the powder and separate, thereby reach the effect of drying and powder separation going on simultaneously, and improve production efficiency.

Specifically, the receiving hopper 103 includes a hopper body 1031, a separating net 1032 is fixedly connected to the inner side wall of the hopper body 1031 near the middle position, and an ash receiving hopper 1033 is installed at the bottom of the separating net 1032.

Through above-mentioned technical scheme, the net aperture that separates 1032 is less than the diameter of activated carbon column, and after the activated carbon column body was dried and is accomplished, open semicircle net door 204, the activated carbon column falls down and falls into on separating net 1032 through pan feeding mouth 207, takes out bucket body 1031, take out the activated carbon column can, convenient and fast.

Specifically, a handle 1034 is fixedly connected to an outer side wall of the bucket body 1031, and the bucket body 1031 is disposed at the bottom of the two inclined plates 102.

Through the technical scheme, the bucket body 1031 is pulled through the handle 1034, so that the activated carbon columns and the powder in the bucket body 1031 can be taken out conveniently and quickly.

Specifically, two ends of the two rotating rods 202 are movably connected with two opposite surfaces of the inner side wall of the box 101, respectively, and one of the rotating rods 202 penetrates through the outer side wall of the box 101, extends to the outside of the box 101, and is coaxially and fixedly connected with the output end of the servo motor 203.

Through above-mentioned technical scheme, fixedly connected with backup pad on the lateral wall of box 101, servo motor 203 installs in the top of backup pad, and servo motor 203 internal line connects for prior art, and no longer gives details here.

Specifically, one side of the semicircular grid door 204 is hinged to the outer side wall of the grid cylinder 201, and the outer side wall of the grid cylinder 201 is provided with a feeding port 207 corresponding to the semicircular grid door 204.

Through the technical scheme, the semicircular grid door 204 is half of the diameter of the grid cylinder 201, and after the semicircular grid door 204 is opened, the activated carbon columns in the grid cylinder 201 can flow out of the material inlet 207 without obstruction, so that the activated carbon columns cannot be blocked and are difficult to fall.

Specifically, the hot air plate 206 includes a box top plate 2061, a wind outlet groove 2062 is fixedly connected to the bottom of the box top plate 2061, a wind conveying pipe 2063 is arranged on the outer side wall of the box top plate 2061, the wind conveying pipe 2063 penetrates through the box top plate 2061 and is communicated with the wind outlet groove 2062, and a hot air blower 2064 is arranged at the other end of the wind conveying pipe 2063.

Through above-mentioned technical scheme, the internal line of air heater 2064 is connected for prior art, and no longer give unnecessary details here, starts air heater 2064, and air heater 2064 sends hot-blast air to air-out groove 2062 department through defeated tuber pipe 2063, and the hot-blast air that air-out groove 2062 department blows to net drum 201 to dry the inside active carbon post of net drum 201.

Specifically, the top plate 2061 is adapted to the top of the box body 101, and a plurality of vent holes 2065 are formed in the outer side wall of the top plate 2061.

Through above-mentioned technical scheme, can produce a large amount of vapor at the stoving active carbon post in-process, the vapor upwards discharges through exhaust hole 2065, accelerates the drying rate of active carbon post.

When the drying device is used, the semicircular grid door 204 is opened and closed, the activated carbon columns which are not subjected to drying treatment are placed into the grid cylinder 201, the servo motor 203 is started, the servo motor 203 drives the grid cylinder 201 to rotate, the hot air plate 206 is opened, the hot air plate 206 blows hot air to the grid cylinder 201, the activated carbon columns in the grid cylinder 201 are dried, dry powder generated in the process can fall onto the two receiving hoppers 103 through gaps in the surface of the grid cylinder 201, the powder on the two receiving hoppers 103 falls onto the receiving hopper 103 below through the interval between the powder and the powder, and the receiving hopper 103 receives the powder for separation.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides an active carbon production is with drying device who has powder separation, is including collecting mechanism (1), its characterized in that: a drying mechanism (2) is arranged in the collecting mechanism (1);

the collecting mechanism (1) comprises a box body (101), inclined plates (102) are fixedly connected to two opposite surfaces of the inner side wall of the box body (101), a material receiving hopper (103) is installed at the inner bottom of the box body (101), a drawing groove (104) is formed in the position, close to the bottom, of the outer side wall of the box body (101), and the material receiving hopper (103) is in sliding connection with the drawing groove (104);

drying mechanism (2) are including net drum (201), equal fixedly connected with bull stick (202) in both ends of net drum (201), the one end of bull stick (202) is provided with servo motor (203), install semicircle net door (204) on the lateral wall of net drum (201), fixedly connected with a plurality of blend stop (205) on the inside wall of net drum (201), the top of net drum (201) is provided with hot-blast plate (206).

2. The drying apparatus for activated carbon production with powder separation according to claim 1, characterized in that: the receiving hopper (103) comprises a hopper body (1031), a separation net (1032) is fixedly connected to the inner side wall of the hopper body (1031) close to the middle position, and a dust receiving hopper (1033) is installed at the bottom of the separation net (1032).

3. The drying apparatus for activated carbon production with powder separation according to claim 2, characterized in that: the outer side wall of the bucket body (1031) is fixedly connected with a handle (1034), and the bucket body (1031) is arranged at the bottoms of the two inclined plates (102).

4. The drying apparatus for activated carbon production with powder separation according to claim 1, characterized in that: two ends of the two rotating rods (202) are movably connected with two opposite surfaces of the inner side wall of the box body (101) respectively, and one of the rotating rods (202) penetrates through the outer side wall of the box body (101), extends to the outside of the box body (101) and is coaxially and fixedly connected with the output end of the servo motor (203).

5. The drying apparatus for activated carbon production with powder separation according to claim 4, characterized in that: one side of the semicircular grid door (204) is hinged with the outer side wall of the grid cylinder (201), and a feeding port (207) corresponding to the semicircular grid door (204) is formed in the outer side wall of the grid cylinder (201).

6. The drying apparatus for activated carbon production with powder separation according to claim 1, characterized in that: the hot blast board (206) is including case roof (2061), the bottom fixedly connected with air-out groove (2062) of case roof (2061), be provided with defeated tuber pipe (2063) on the lateral wall of case roof (2061), defeated tuber pipe (2063) run through case roof (2061) and link up each other with air-out groove (2062), the other end of defeated tuber pipe (2063) is provided with air heater (2064).

7. The drying apparatus for activated carbon production with powder separation according to claim 6, characterized in that: the box top plate (2061) is matched with the top of the box body (101), and a plurality of exhaust holes (2065) are formed in the outer side wall of the box top plate (2061).

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