CN114408583A

CN114408583A - Storm formula adsorbent feeder

Info

Publication number: CN114408583A
Application number: CN202210184247.8A
Authority: CN
Inventors: 郑建国
Original assignee: Hangzhou Rizhisheng Purification Equipment Co ltd
Current assignee: Hangzhou Rizhisheng Purification Equipment Co ltd
Priority date: 2022-02-23
Filing date: 2022-02-23
Publication date: 2022-04-29
Anticipated expiration: 2042-02-23
Also published as: CN114408583B

Abstract

The invention discloses a storm-snow type adsorbent feeder, which comprises a filling device, a hose and a discharging device, wherein the top parts of the filling device and the discharging device are connected through the hose, the filling device comprises a material suction pipe, a pressurizing mixing pipe and a negative pressure generating mechanism, the discharging device comprises a fixed inner pipe, a lifting outer pipe and a discharging pipe, the negative pressure generating mechanism generates negative pressure, so that adsorbent particles are sucked through the material suction pipe and enter the pressurizing mixing pipe, then the mixture is conveyed into the fixed inner pipe through a hose, the bottom of the lifting outer pipe firstly descends to the lower part of the adsorption cylinder to be charged, in the feeding process, the lifting outer pipe gradually rotates and rises, the adsorbent is sprayed out from two ends of the blanking pipe, can realize that the successive layer loads in the adsorption cylinder for the range of adsorbent is neat, also can avoid the impact of adsorbent and the range that leads to is in disorder and friction pulverization simultaneously.

Description

Storm formula adsorbent feeder

Technical Field

The invention relates to the technical field of adsorbent addition, in particular to a snowstorm type adsorbent feeder.

Background

The adsorbent is also called absorbent, is a solid substance which can effectively adsorb some components in gas or liquid and has a large specific surface, a proper pore structure and a surface structure; strong adsorption capacity to adsorbates; generally do not chemically react with the adsorbate and the media; the manufacturing is convenient and the regeneration is easy; has excellent adsorbability and mechanical property.

In the production process of chemical production (such as sulfur oxide or aluminum oxide), the application of the adsorbent is very common, the adsorbent needs to be added into an adsorption cylinder for use, the addition of the adsorbent is generally carried out manually in the prior art, and the addition mode has some disadvantages:

firstly, adding an adsorbent into an adsorption cylinder manually through a shovel and the like, wherein the addition of the adsorbent is not uniform enough;

secondly, when the adsorbent falls in the adsorption cylinder, the adsorbent falls from the high position at the top of the adsorption cylinder, so that impact is generated, and the arrangement of the adsorbent is messy; the performance of the adsorbent can also be affected by the mutual friction powdering between the adsorbents when the adsorbents bounce.

Disclosure of Invention

In order to solve the problems, the invention provides a storm type adsorbent feeder, which is realized by the following technical scheme.

A storm type adsorbent feeder comprises a filling device, a hose and a discharging device, wherein the tops of the filling device and the discharging device are connected through the hose;

the filling device comprises a material suction pipe, a pressurizing mixing pipe and a negative pressure generating mechanism; the negative pressure generating mechanism comprises a vertical connecting pipe and a transverse connecting pipe, the vertical connecting pipe is positioned in the material suction pipe, the axes of the vertical connecting pipe and the material suction pipe are superposed, the transverse connecting pipe is positioned on the right side of the material suction pipe, an L-shaped elbow is fixedly connected to the right side of the material suction pipe, the bottom of the vertical connecting pipe and the left end of the transverse connecting pipe are respectively butted with two ends of the elbow, a nozzle is fixedly connected to the top of the vertical connecting pipe, and the right end of the transverse connecting pipe is connected with an external air compression pump;

the blanking device comprises a fixed inner tube, a lifting outer tube and a blanking tube, the top of the fixed inner tube is fixedly connected with one end, far away from the filling device, of the hose, the lifting outer tube is sleeved on the lower portion of the fixed inner tube, and the blanking tube is fixedly connected to the bottom of the lifting outer tube.

Furthermore, a first flange plate is fixedly connected to the top of the material suction pipe and one end, far away from the blanking device, of the hose, a second flange plate is symmetrically and fixedly connected to the upper end and the lower end of the pressurizing mixing pipe, the corresponding first flange plate and the corresponding second flange plate are connected through a bolt assembly, and a sealing gasket is further arranged between the corresponding first flange plate and the corresponding second flange plate.

Furthermore, a pressurizing seat is arranged in the pressurizing mixing pipe, a pressurizing cavity is formed in the pressurizing seat, and the upper end and the lower end of the pressurizing seat are both horn-shaped openings.

Furthermore, the outer wall of the fixed inner pipe is provided with a spiral groove, the inner wall of the lifting outer pipe is fixedly connected with a spiral blade matched with the spiral groove, the center of the lifting outer pipe is further provided with a mounting seat, the mounting seat is located below the spiral blade, and fan blades are fixedly connected between the mounting seat and the inner wall of the lifting outer pipe in a circumferential uniform mode.

Further, when the fan blades are subjected to positive airflow from top to bottom, the rotating direction of the fan blades is consistent with the spiral ascending direction of the spiral blades along the spiral groove.

Furthermore, an inclined screen is fixedly connected to the middle of the feeding pipe, the sizes of the adsorbent particles to be fed are different, and the mesh size of the screen is consistent with the median of the sizes of the adsorbent particles.

Furthermore, the discharge pipes on two sides of the screen are symmetrically and fixedly connected with orientation seats, fine particle orientation grooves and coarse particle orientation grooves are formed in the orientation seats on the left side and the right side respectively, the cross sections of the fine particle orientation grooves and the coarse particle orientation grooves are rectangular, and the adsorbent particles to be fed are cylindrical.

The invention has the advantages that the negative pressure generating mechanism generates negative pressure, so that adsorbent particles are sucked through the suction pipe and enter the pressurizing mixing pipe, and then are conveyed into the fixed inner pipe through the hose, the bottom of the lifting outer pipe firstly descends to the lower part of the adsorption cylinder to be charged, the lifting outer pipe gradually rotates and ascends in the charging process, the adsorbent is sprayed out from the two ends of the blanking pipe, the adsorption cylinder can be charged layer by layer, the adsorbent is orderly arranged, and the messy arrangement and friction pulverization caused by the impact of the adsorbent can be avoided.

Drawings

In order to more clearly illustrate the technical solution of the present invention, the drawings used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without inventive labor.

FIG. 1: the invention relates to an axonometric view of a snowstorm type adsorbent feeder;

FIG. 2: FIG. 1 shows a close-up view at A;

FIG. 3: the internal structure of the filling device is shown schematically;

FIG. 4: FIG. 3 is a partial enlarged view of the point B;

FIG. 5: the invention relates to a sectional view of a blanking device;

FIG. 6: the internal structure of the blanking pipe is schematic.

The reference numbers are as follows:

11-material suction pipe, 12-pressurizing mixing pipe, 131-vertical connecting pipe, 132-horizontal connecting pipe, 133-elbow, 134-nozzle, 14-outer cylinder, 15-material suction hole, 16-pressurizing seat and 17-pressurizing cavity;

2-a hose;

31-fixed inner tube, 32-lifting outer tube and 33-discharging tube;

41-a first flange, 42-a second flange, 43-a bolt assembly, 44-a sealing gasket;

51-helical flute, 52-helical blade, 53-mount, 54-fan blade, 61-screen, 62-orientation seat, 63-fine orientation flute, 64-coarse orientation flute.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

As shown in fig. 1-6, a snowstorm type adsorbent feeder comprises a filling device, a hose 2 and a blanking device, wherein the tops of the filling device and the blanking device are connected through the hose 2;

the filling device comprises a material suction pipe 11, a pressurizing mixing pipe 12 and a negative pressure generating mechanism; the pressurizing mixing pipe 12 is butted right above the material suction pipe 11, the lower part of the material suction pipe 11 is fixedly connected with an outer cylinder 14, material suction holes 15 are densely distributed on a side plate of the outer cylinder 14, the negative pressure generating mechanism comprises a vertical connecting pipe 131 and a transverse connecting pipe 132, the vertical connecting pipe 131 is positioned in the material suction pipe 11, the axes of the vertical connecting pipe 131 and the material suction pipe 11 are superposed, the transverse connecting pipe 132 is positioned on the right side of the material suction pipe 11, the right side of the material suction pipe 11 is also fixedly connected with an L-shaped elbow 133, the bottom of the vertical connecting pipe 131 and the left end of the transverse connecting pipe 132 are respectively butted with two ends of the elbow 133, the top of the vertical connecting pipe 131 is also fixedly connected with a nozzle 134, and the right end of the transverse connecting pipe 132 is connected with an external air compression pump;

the blanking device comprises a fixed inner tube 31, a lifting outer tube 32 and a blanking tube 33, the top of the fixed inner tube 31 is fixedly connected with one end, far away from the filling device, of the hose 2, the lifting outer tube 32 is sleeved on the lower portion of the fixed inner tube 31, and the blanking tube 33 is fixedly connected to the bottom of the lifting outer tube 32.

Preferably, a first flange 41 is fixedly connected to the top of the material suction pipe 11 and one end of the hose 2 away from the blanking device, second flanges 42 are symmetrically and fixedly connected to the upper and lower ends of the pressurized mixing pipe 12, the corresponding first flange 41 and the corresponding second flange 42 are connected by a bolt assembly 43, and a sealing gasket 44 is further disposed between the corresponding first flange 41 and the corresponding second flange 42.

Preferably, a pressurizing seat 16 is arranged in the pressurizing mixing pipe 12, a pressurizing cavity 17 is arranged in the pressurizing seat 16, and the upper end and the lower end of the pressurizing seat 16 are both horn-shaped openings.

Preferably, the outer wall of the fixed inner tube 31 is provided with a spiral groove 51, the inner wall of the lifting outer tube 32 is fixedly connected with a spiral blade 52 matched with the spiral groove 51, the center of the lifting outer tube 32 is further provided with a mounting seat 53, the mounting seat 53 is located below the spiral blade 52, and fan blades 54 are uniformly and fixedly connected between the mounting seat 53 and the inner wall of the lifting outer tube 32 in the circumferential direction.

Preferably, when the fan blade 54 receives a positive airflow from the top to the bottom, the rotation direction of the fan blade 54 coincides with the spiral ascending direction of the spiral blade 52 along the spiral groove 51.

Preferably, an inclined screen 61 is fixedly connected to the middle part of the feeding pipe 33, the sizes of the adsorbent particles to be fed are different, and the mesh size of the screen 61 is consistent with the median of the sizes of the adsorbent particles.

Preferably, the orientation seats 62 are symmetrically and fixedly connected to the blanking pipes 33 on both sides of the screen 61, the orientation seats 62 on the left and right sides are respectively provided with a fine particle orientation tank 63 and a coarse particle orientation tank 64, the cross sections of the fine particle orientation tank 63 and the coarse particle orientation tank 64 are rectangular, and the adsorbent particles to be fed are cylindrical.

One embodiment of the present invention is:

before the feeder is used, the equipment is firstly assembled as shown in fig. 1, then the bottom of the outer cylinder 14 is inserted into the adsorbent containing box, the blanking device is placed into the adsorption cylinder, and the blanking pipe 33 enters the bottom of the adsorption cylinder under the action of gravity.

Then, an external air compression pump is started, compressed air sequentially passes through the transverse connecting pipe 132, the elbow 133 and the vertical connecting pipe 131 and is then sprayed out of the nozzle 134, the sprayed air flow rapidly flows from bottom to top in the pressurizing and mixing pipe 12, and the rapidly flowing air forms negative pressure as seen from bernoulli.

By the arrangement of the booster seat 16 and the booster cavity 17, the flow speed of the air in the booster cavity 17 is increased, and the pressure therein is further reduced.

Due to the formation of negative pressure, the adsorbent particles enter the material suction pipe 11 and the pressurizing mixing pipe 12 through the material suction holes 15 and are uniformly mixed with air.

The mixture of air and sorbent particles enters the fixed inner tube 31 and the riser outer tube 32 through the hose 2.

The positive air flow from top to bottom acts on the fan blades 54, so that the fan blades 54 rotate, and then the integral structure of the lifting outer tube 32, the blanking tube 33 and the fan blades 54 rotates, and the lifting outer tube 32 gradually rises when rotating due to the fact that the lifting outer tube 32 is matched with the spiral groove 51 on the fixed inner tube 31 through the spiral blades 52.

The adsorbent granule sprays and goes out through the both ends of unloading pipe 33, and the rotation of cooperation unloading pipe 33 rises to carry out from ascending successive layer reinforced from down to the inside of adsorbing the section of thick bamboo.

When the adsorbent particles are sprayed onto the screen 61, the adsorbent particles are screened by the screen 61, the adsorbent with larger size is intercepted by the screen 61 and enters the right side of the blanking pipe 33, the adsorbent with smaller size enters the left side of the blanking pipe 33 through the screen 61, and the adsorbent particles on the left side and the adsorbent particles on the right side are sequentially discharged through a fine particle directional tank 63 and a coarse particle directional tank 64 respectively.

So that the adsorbent particles can be arranged in the adsorption cylinder in order.

Above-mentioned reinforced in-process can be so that adsorbent granule neatly arranges, and when upwards successive layer adds the adsorbent from the follow, can avoid the impact of adsorbent and the arrangement that leads to is in disorder and friction pulverization.

The preferred embodiments of the invention disclosed above are intended to be illustrative only. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise forms disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, to thereby enable others skilled in the art to best utilize the invention. The invention is limited only by the claims and their full scope and equivalents.

Claims

1. The utility model provides a snowstorm formula adsorbent feeder which characterized in that: the device comprises a filling device, a hose (2) and a blanking device, wherein the filling device is connected with the top of the blanking device through the hose (2);

the filling device comprises a material suction pipe (11), a pressurizing mixing pipe (12) and a negative pressure generating mechanism; the negative pressure generating mechanism comprises a vertical connecting pipe (131) and a transverse connecting pipe (132), the vertical connecting pipe (131) is positioned in the material suction pipe (11), the axes of the vertical connecting pipe (131) and the material suction pipe (11) are overlapped, the transverse connecting pipe (132) is positioned on the right side of the material suction pipe (11), an L-shaped elbow (133) is fixedly connected to the right side of the material suction pipe (11), the bottom of the vertical connecting pipe (131) and the left end of the transverse connecting pipe (132) are respectively in butt joint with two ends of the elbow (133), a nozzle (134) is fixedly connected to the top of the vertical connecting pipe (131), and the right end of the transverse connecting pipe (132) is connected with an external air compression pump;

the blanking device comprises a fixed inner tube (31), a lifting outer tube (32) and a blanking tube (33), the top of the fixed inner tube (31) is fixedly connected with one end of a hose (2) far away from the packing device, the lifting outer tube (32) is sleeved on the lower portion of the fixed inner tube (31), and the blanking tube (33) is fixedly connected to the bottom of the lifting outer tube (32).

2. The snowstorm sorbent feeder of claim 1, wherein: inhale the top of material pipe (11) and hose (2) and keep away from unloader's one end rigid coupling and have first ring flange (41), the upper and lower both ends symmetry rigid coupling of pressure boost hybrid tube (12) has second ring flange (42), and first ring flange (41) and second ring flange (42) that correspond pass through bolt assembly (43) and connect, still are equipped with sealed pad (44) between first ring flange (41) and the second ring flange (42) that correspond.

3. The snowstorm sorbent feeder of claim 1, wherein: the booster mixing pipe is characterized in that a booster seat (16) is arranged in the booster mixing pipe (12), a booster cavity (17) is formed in the booster seat (16), and the upper end and the lower end of the booster seat (16) are both horn-shaped openings.

4. The snowstorm sorbent feeder of claim 1, wherein: spiral groove (51) have been seted up to the outer wall of fixed inner tube (31), the inner wall rigid coupling of lift outer tube (32) have with spiral groove (51) adaptation helical blade (52), the center of lift outer tube (32) still is equipped with mount pad (53), mount pad (53) are located the below of helical blade (52), the even rigid coupling of circumference has flabellum (54) between the inner wall of mount pad (53) and lift outer tube (32).

5. The snowstorm sorbent feeder of claim 4, wherein: when the fan blades are subjected to positive air flow from top to bottom, the rotating direction of the fan blades is consistent with the spiral lifting direction of the spiral blades (52) along the spiral groove (51).

6. The snowstorm sorbent feeder of claim 1, wherein: an inclined screen (61) is fixedly connected to the middle of the discharging pipe (33), the sizes of the adsorbent particles to be charged are different, and the mesh size of the screen (61) is consistent with the median of the sizes of the adsorbent particles.

7. The snowstorm sorbent feeder of claim 6, wherein: the feeding pipes (33) on the two sides of the screen (61) are symmetrically and fixedly connected with orientation seats (62), fine particle orientation grooves (63) and coarse particle orientation grooves (64) are formed in the orientation seats (62) on the left side and the right side respectively, the sections of the fine particle orientation grooves (63) and the coarse particle orientation grooves (64) are rectangular, and adsorbent particles to be fed are cylindrical.