CN218077943U - Adjustable material separating cone of active carbon analysis tower - Google Patents

Abstract

The utility model belongs to the technical field of the active carbon production facility, concretely relates to branch material awl with adjustable active carbon analytic tower, awl under the analytic tower, the inside equidistance of awl slides the equipment under the analytic tower has main branch material awl, the inside equidistance of awl slides the equipment under the analytic tower has inferior branch material awl, just main branch material awl with inferior branch material awl connects the formula equipment one by one, the bottom both sides outer wall of awl is all fixed the equipment to have the dust absorption subassembly under the analytic tower, the both sides inner wall of awl casing is all fixed and is provided with main slide rail, awl shells inner wall is located the below of inferior slide rail is all fixed and is provided with down the slide rail. The utility model discloses can realize adjusting the effect of unloading speed and blanking flow, make unloading work have nimble adjustable characteristics, the problem that the dust flies upward when can also solving the blanking in addition avoids the staff to inhale too much dust, in addition, kinetic energy when the power of this work utilizes the material whereabouts just can realize.

Description

Adjustable material separating cone of active carbon analysis tower

Technical Field

The utility model belongs to the technical field of the active carbon production facility, concretely relates to branch material awl with adjustable active carbon analytic tower.

Background

Activated carbon is a specially treated carbon, in which organic materials (shells, coal, wood, etc.) are heated in the absence of air to reduce non-carbon components (this process is called carbonization), and then reacted with gas to erode the surface and produce a structure with developed micropores (this process is called activation); because the activation process is a microscopic process, namely the surface erosion of a large amount of molecular carbides is point-shaped erosion, countless fine pores are formed on the surface of the activated carbon; the diameter of micropores on the surface of the activated carbon is mostly between 2 nm and 50nm, even a small amount of activated carbon has huge surface area, the surface area of each gram of activated carbon is 500-1500 m < 2 >, and all the applications of the activated carbon are almost based on the characteristic of the activated carbon.

The problems existing in the prior art are as follows:

in the production technology of the existing activated carbon, the traditional separation cone of the resolving tower does not have the function of blanking regulation, so that the blanking speed and the blanking flow are not controllable, and further subsequent work cannot timely follow up, the speed between the works cannot be flexibly allocated, and in addition, during material blanking, a large amount of dust can be raised at the bottom of the separation cone to seriously affect the working environment.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a branch material awl with adjustable active carbon analytic tower can realize adjusting the effect of unloading speed and blanking flow, makes unloading work have nimble adjustable characteristics, and the problem that the dust flies upward when can also solving the blanking in addition avoids the staff to inhale too much dust, and in addition, kinetic energy when the power of this work utilizes the material whereabouts just can realize.

The utility model discloses the technical scheme who takes specifically as follows:

an adjustable material distribution cone of an active carbon analysis tower comprises an analysis tower lower cone, a main material distribution cone is assembled inside the analysis tower lower cone in an equidistant sliding mode, secondary material distribution cones are assembled inside the analysis tower lower cone in an equidistant sliding mode, the main material distribution cones and the secondary material distribution cones are assembled in a successive mode one by one, and dust absorption assemblies are fixedly assembled on the outer walls of two sides of the bottom of the analysis tower lower cone;

the analytic tower lower cone further comprises a cone shell, the inner walls of two sides of the cone shell are fixedly provided with a main upper sliding rail, the inner wall of the cone shell is located an auxiliary upper sliding rail is fixedly arranged below the main upper sliding rail, and the inner wall of the cone shell is located a lower sliding rail is fixedly arranged below the auxiliary upper sliding rail.

The two ends of the main distributing cone and the secondary distributing cone are fixedly provided with sliding blocks, the sliding blocks at the two ends of the main distributing cone are embedded into the main upper sliding rail and the lower sliding rail in a sliding manner, and the sliding blocks at the two ends of the secondary distributing cone are embedded into the secondary upper sliding rail and the lower sliding rail in a sliding manner.

The main upper sliding rail and the secondary upper sliding rail are all provided with penetrating grooves, and stop blocks are assembled inside the penetrating grooves in a sliding mode.

The two check blocks are respectively arranged on two sides of one sliding block, and the top ends of the check blocks are screwed with fixing screws.

The dust absorption assembly further comprises absorption barrels, barrel shells are arranged on two sides of the bottom of the conical shell, and the two absorption barrels are fixedly arranged at two ends of the outer wall of one barrel shell respectively.

The blanking roller is rotatably arranged in the barrel shell, the fan blades are rotatably arranged at one end of the absorption barrel, and the two ends of the blanking roller are in transmission connection with the two adjacent fan blades through a belt sleeved on the blanking roller.

The inside filter screen that is close to of absorption cylinder the one end of fan blade all installs, the absorption cylinder is kept away from the equal fixed connection absorption tube of one end of fan blade, the terminal orientation of absorption tube the bottom of awl casing.

The utility model discloses the technological effect who gains does:

(1) The utility model discloses, when the awl was used under the analytic tower, the material passed the awl casing, under the effect of stopping and dividing the material of main branch material awl and inferior branch material awl, can realize adjusting the effect of unloading speed and blanking flow, made the unloading work have nimble adjustable characteristics.

(2) The utility model discloses, the material is at the in-process that passes the awl casing, the impact force of material can make the blanking rolling car rotatory, the fan blade will be rotatory after the transmission, and make the inside suction that produces of absorption cylinder, therefore, the dust of kicking up during the blanking will be sucked inside the absorption cylinder through the absorption tube, this process, the problem that the dust flies upward when can solve the blanking, avoid the staff to suck too much dust, in addition, kinetic energy when the power of this work utilizes the material whereabouts just can realize, do not need extra power equipment to realize, have energy saving and emission reduction's characteristics.

Drawings

Fig. 1 is a front perspective view provided by an embodiment of the present invention;

fig. 2 is an internal structure diagram of a lower cone of a desorption tower provided in an embodiment of the present invention;

FIG. 3 is an enlarged partial view of the structure A of FIG. 2;

fig. 4 is an assembled structural view of a dust absorption assembly according to an embodiment of the present invention;

fig. 5 is an internal structure view of an absorption tube according to an embodiment of the present invention.

In the drawings, the reference numbers indicate the following list of parts:

1. a lower cone of the resolution tower; 101. a cone housing; 102. a cartridge housing; 103. a main upper slide rail; 104. a secondary upper slide rail; 105. a lower slide rail; 106. penetrating a groove; 107. a stopper; 108. a fixing screw; 2. a main material distributing cone; 21. a slider; 3. a secondary material-distributing cone; 4. a dust absorbing assembly; 401. an absorption cylinder; 402. an absorber tube; 403. blanking rolling; 404. a belt; 405. a fan blade; 406. and (5) filtering by using a filter screen.

Detailed Description

In order to make the objects and advantages of the present invention more apparent, the present invention will be described in detail with reference to the following embodiments. It is to be understood that the following text is only intended to describe one or several particular embodiments of the invention, and does not strictly limit the scope of the claims specifically claimed.

As shown in fig. 1-5, an adjustable distribution cone of an active carbon analysis tower comprises an analysis tower lower cone 1, a main distribution cone 2 is assembled inside the analysis tower lower cone 1 in an equidistance sliding mode, a secondary distribution cone 3 is assembled inside the analysis tower lower cone 1 in an equidistance sliding mode, the main distribution cone 2 and the secondary distribution cone 3 are assembled in a successive mode one by one, and dust absorption assemblies 4 are fixedly assembled on outer walls of two sides of the bottom of the analysis tower lower cone 1.

Referring to fig. 2, the lower cone 1 of the analysis tower further includes a cone housing 101, the inner walls of the two sides of the cone housing 101 are fixedly provided with a primary upper slide rail 103, the inner wall of the cone housing 101 is located below the primary upper slide rail 103 and is fixedly provided with a secondary upper slide rail 104, the inner wall of the cone housing 101 is located below the secondary upper slide rail 104 and is fixedly provided with a lower slide rail 105, the surfaces of the primary upper slide rail 103 and the secondary upper slide rail 104 are respectively provided with a through groove 106, a stopper 107 is slidably assembled inside the through groove 106, the top end of the stopper 107 is respectively screwed with a fixing screw 108, the primary distribution cone 2 and the secondary distribution cone 3 are installed inside the lower cone 1 of the analysis tower, and the primary distribution cone 2 and the secondary distribution cone 3 are alternately assembled one by one, in the installation process, the sliders 21 at the two ends of the primary distribution cone 2 slide inside the primary upper slide rail 103 and the lower slide rail 105, and the sliders 21 at the two ends of the secondary distribution cone 3 slide inside the secondary upper slide rail 104 and the lower slide rail 105.

Referring to fig. 2 and 3, the two ends of the main distributing cone 2 and the secondary distributing cone 3 are both fixedly provided with a sliding block 21, the sliding blocks 21 at the two ends of the main distributing cone 2 are slidably embedded into the main upper sliding rail 103 and the lower sliding rail 105, the sliding blocks 21 at the two ends of the secondary distributing cone 3 are slidably embedded into the secondary upper sliding rail 104 and the lower sliding rail 105, the two stoppers 107 are respectively arranged at two sides of one sliding block 21, when the main distributing cone 2 and the secondary distributing cone 3 move to the designated positions, the stoppers 107 are respectively moved to two sides of the sliding block 21 and are finally fixed by the fixing screws 108.

Referring to fig. 4 and 5, the dust absorption assembly 4 further includes absorption cylinders 401, the two sides of the bottom of the conical shell 101 are respectively provided with the cylinder shell 102, the two absorption cylinders 401 are respectively and fixedly disposed at two ends of the outer wall of one cylinder shell 102, the interior of the cylinder shell 102 is respectively and rotatably provided with a blanking roller 403, one end of the interior of the absorption cylinder 401 is respectively and rotatably provided with a fan blade 405, two ends of the blanking roller 403 are in transmission connection with two adjacent fan blades 405 through a sleeved belt 404, one end of the interior of the absorption cylinder 401 close to the fan blade 405 is respectively and rotatably provided with a filter screen 406, one end of the absorption cylinder 401 far away from the fan blade 405 is respectively and fixedly connected with an absorption tube 402, the tail end of the absorption tube 402 faces the bottom of the conical shell 101, during the process of the material passing through the conical shell 101, the impact force of the material can make the blanking roller 403 rotate, then the fan blade 405 is driven by the belt 404 to rotate inside the absorption cylinder 401, so as to generate suction inside the absorption cylinder 401, therefore, the dust raised during blanking can be sucked into the absorption cylinder 401 through the absorption tube 402, and the solid-gas separation of the filter screen 406 can be realized.

The utility model discloses a theory of operation does: the method comprises the following steps that a main distributing cone 2 and a secondary distributing cone 3 are installed inside a lower cone 1 of an analytic tower, and the main distributing cone 2 and the secondary distributing cone 3 are assembled one by one in a replacing manner, in the installation process, sliding blocks 21 at two ends of the main distributing cone 2 slide inside a main upper sliding rail 103 and a lower sliding rail 105, sliding blocks 21 at two ends of the secondary distributing cone 3 slide inside a secondary upper sliding rail 104 and a lower sliding rail 105, when the main distributing cone 2 and the secondary distributing cone 3 move to specified positions, a plurality of stopping blocks 107 are respectively moved to two sides of the sliding blocks 21 and are finally fixed through fixing screws 108, when the lower cone 1 of the analytic tower is used, materials penetrate through a cone shell 101, under the blocking and distributing effects of the main distributing cone 2 and the secondary distributing cone 3, the effects of adjusting the blanking speed and the blanking flow can be achieved, and the blanking work has the characteristic of flexibility and adjustability;

in addition, in the process that the materials penetrate through the conical shell 101, the impact force of the materials can enable the blanking roller 403 to rotate, then the fan blades 405 are driven by the belt 404 to rotate inside the absorption cylinder 401, and further suction force is generated inside the absorption cylinder 401, so that dust raised during blanking can be sucked into the absorption cylinder 401 through the absorption pipe 402, solid-gas separation is achieved under the effect of the filter screen 406, and finally the dust is collected inside the absorption cylinder 401.

The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, a plurality of modifications and decorations can be made without departing from the principle of the present invention, and these modifications and decorations should also be regarded as the protection scope of the present invention. The structures, devices, and methods of operation of the present invention, not specifically described and illustrated, are generally practiced by those of ordinary skill in the art without specific recitation or limitation.

Claims (7)

1. The utility model provides a branch material awl with adjustable active carbon analytic tower, includes analytic tower awl (1) down, its characterized in that: the inner part of the lower cone (1) of the analysis tower is equidistantly and slidably assembled with a main distributing cone (2), the inner part of the lower cone (1) of the analysis tower is equidistantly and slidably assembled with a secondary distributing cone (3), the main distributing cone (2) and the secondary distributing cone (3) are assembled one by one in a replacing manner, and the outer walls of two sides of the bottom of the lower cone (1) of the analysis tower are fixedly assembled with dust absorption components (4);

analysis tower awl (1) still includes awl casing (101), the both sides inner wall of awl casing (101) is all fixed to be provided with main slide rail (103) of going up, awl casing (101) inner wall is located the below of main slide rail (103) of going up is all fixed to be provided with inferior slide rail (104), awl casing (101) inner wall is located the below of inferior slide rail (104) is all fixed to be provided with down slide rail (105).

2. The adjustable material-separating cone of the activated carbon desorption tower as claimed in claim 1, wherein: the material distributing device is characterized in that sliding blocks (21) are fixedly arranged at two ends of the main material distributing cone (2) and the secondary material distributing cone (3), the sliding blocks (21) at the two ends of the main material distributing cone (2) are slidably embedded into the main upper sliding rail (103) and the lower sliding rail (105), and the sliding blocks (21) at the two ends of the secondary material distributing cone (3) are slidably embedded into the secondary upper sliding rail (104) and the lower sliding rail (105).

3. The adjustable material-separating cone of the activated carbon desorption tower as claimed in claim 2, wherein: the main upper sliding rail (103) and the secondary upper sliding rail (104) are both provided with through grooves (106), and stop blocks (107) are assembled inside the through grooves (106) in a sliding mode.

4. The adjustable material-separating cone of the activated carbon analysis tower according to claim 3, characterized in that: the two stop blocks (107) are respectively arranged on two sides of one sliding block (21), and the top ends of the stop blocks (107) are respectively screwed with fixing screws (108).

5. The adjustable material-separating cone of the activated carbon desorption tower as claimed in claim 1, wherein: the dust absorption assembly (4) further comprises absorption cylinders (401), the two sides of the bottom of the conical shell (101) are respectively provided with a cylinder shell (102), and the two absorption cylinders (401) are respectively and fixedly arranged at two ends of the outer wall of one cylinder shell (102).

6. The adjustable material-separating cone of the activated carbon analysis tower according to claim 5, wherein: the blanking roller (403) is rotatably mounted in the barrel shell (102), fan blades (405) are rotatably mounted at one end of the interior of the absorption barrel (401), and two ends of the blanking roller (403) are in transmission connection with two adjacent fan blades (405) through belts (404) sleeved with each other.

7. The adjustable material-separating cone of the activated carbon desorption tower as claimed in claim 6, wherein: a filter screen (406) is installed at one end, close to the fan blade (405), in the absorption cylinder (401), one end, far away from the fan blade (405), of the absorption cylinder (401) is fixedly connected with an absorption pipe (402), and the tail end of the absorption pipe (402) faces towards the bottom of the conical shell (101).

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