CN113137849A

CN113137849A - Molecular sieve forming and drying mechanism

Info

Publication number: CN113137849A
Application number: CN202110432306.4A
Authority: CN
Inventors: 王成; 王勇
Original assignee: Nanjing Yongcheng Molecular Sieve Co ltd
Current assignee: Nanjing Yongcheng Molecular Sieve Co ltd
Priority date: 2021-04-21
Filing date: 2021-04-21
Publication date: 2021-07-20

Abstract

The invention discloses a molecular sieve forming and drying mechanism which comprises a box body, wherein a fixing plate is fixedly arranged in the box body, the fixing plate divides the interior of the box body into a first cavity and a second cavity, a first transmission belt is arranged in the first cavity, a second transmission belt is arranged in the second cavity, a through groove is formed in the fixing plate, and an inclined plate is arranged at the bottom of the through groove. According to the invention, the driving motor is started to drive the rotating disc to rotate, the eccentric rod is driven to slide in the groove, the moving block is driven to do reciprocating motion in the vertical direction, the piston is driven to do reciprocating motion in the compression cylinder, the piston moves upwards, the compression cylinder sucks hot air in the first cavity through the air inlet pipe, the piston moves downwards to discharge the hot air in the compression cylinder into the second cavity through the air outlet pipe, and the hot air performs secondary drying on the molecular sieve on the second conveying belt, so that the hot air is recycled, the resource utilization efficiency is improved, and the energy is saved.

Description

Molecular sieve forming and drying mechanism

Technical Field

The invention relates to the technical field of drying mechanisms, in particular to a molecular sieve forming and drying mechanism.

Background

The molecular sieve is an artificially synthesized hydrated aluminosilicate or natural zeolite with the function of screening molecules, and has a plurality of pore passages with uniform pore diameters and holes arranged in order in the structure, the molecular sieves with different pore diameters separate molecules with different sizes and shapes, and the molecular sieve has the advantages of high adsorption capacity, strong selectivity and high temperature resistance, and is widely applied to organic chemical industry and petrochemical industry.

In order to remove moisture adsorbed in a molecular sieve in a production process, the molecular sieve needs to be dried, and the molecular sieve is dried through a drying mechanism.

Disclosure of Invention

In order to solve the technical problems mentioned in the background art, a molecular sieve forming and drying mechanism is provided.

In order to achieve the purpose, the invention adopts the following technical scheme:

a molecular sieve forming and drying mechanism comprises a box body, wherein a fixed plate is fixedly arranged in the box body, the fixed plate divides the box body into a first cavity and a second cavity, a first transmission belt is arranged in the first cavity, a second transmission belt is arranged in the second cavity, a through groove is formed in the fixed plate, an inclined plate is arranged at the bottom of the through groove, the inclined plate is arranged above the second transmission belt, and a heating plate is fixedly arranged above the first transmission belt;

fixed mounting has feed hopper on the box, be equipped with the control mechanism who changes feed hopper discharge gate size in the box, box one side is equipped with steam recovery unit, steam recovery unit one end intercommunication has the intake pipe, the free end and the first chamber intercommunication of intake pipe, steam recovery unit's other end intercommunication has the outlet duct, the free end and the second chamber intercommunication of outlet duct.

As a further description of the above technical solution:

the hot gas recovery device comprises an installation box, a compression cylinder is fixedly installed in the installation box, a piston is connected in the compression cylinder in a sliding mode, an air inlet pipe and an air outlet pipe are communicated with the bottom of the compression cylinder, a first driving mechanism for driving the piston to reciprocate is arranged in the installation box, a one-way valve is installed in the air inlet pipe, and a one-way valve is installed in the air outlet pipe.

As a further description of the above technical solution:

the first driving mechanism comprises a driving motor, a lifting rod is fixedly mounted at the top of the piston, a moving block is fixedly mounted at the top of the lifting rod, a groove is formed in the moving block, the driving motor is fixedly mounted in the mounting box, a rotating disc is connected to an output shaft of the driving motor in a transmission manner, and an eccentric rod which slides in the groove is fixedly connected to the rotating disc.

As a further description of the above technical solution:

department's intercommunication has dehydrating unit in the middle of the intake pipe, dehydrating unit is including the dehumidification case, dehumidification incasement fixed mounting has a plurality of fixed blocks, the mounting groove has been seted up in the fixed block, the mounting groove intussuseption is filled with the water absorbent, set up a plurality of air grooves that communicate with the mounting groove in the fixed block.

As a further description of the above technical solution:

the plurality of vent grooves are arranged on the fixed block at equal intervals.

As a further description of the above technical solution:

the first conveying belt and the second conveying belt are metal conveying belts.

As a further description of the above technical solution:

control mechanism includes the shutoff piece, the shutoff piece is installed to the box internal rotation, the installation piece that shutoff piece bottom fixedly connected with slope set up, the sliding tray has been seted up in the installation piece, fixed mounting has the center pin in the box, it installs the turning block to rotate on the center pin, turning block one end fixedly connected with is at the gliding slide bar of sliding tray, be equipped with drive turning block pivoted second actuating mechanism in the box.

As a further description of the above technical solution:

the water absorbent is calcium oxide.

As a further description of the above technical solution:

the second driving mechanism comprises an air cylinder, the other end of the rotating block is rotatably provided with a connecting rod, the air cylinder is fixedly arranged in the box body, and a piston rod of the air cylinder is rotatably arranged with the free end of the connecting rod.

As a further description of the above technical solution:

the sliding rod is welded on the rotating block.

In summary, due to the adoption of the technical scheme, the invention has the beneficial effects that:

1. according to the invention, the driving motor is started to drive the rotating disc to rotate, the eccentric rod is driven to slide in the groove, the moving block is driven to do reciprocating motion in the vertical direction, the piston is driven to do reciprocating motion in the compression cylinder, the piston moves upwards, the compression cylinder sucks hot air in the first cavity through the air inlet pipe, the piston moves downwards to discharge the hot air in the compression cylinder into the second cavity through the air outlet pipe, and the hot air performs secondary drying on the molecular sieve on the second conveying belt, so that the hot air is recycled, the resource utilization efficiency is improved, and the energy is saved.

2. According to the invention, the piston rod of the starting cylinder retracts, the rotating block is driven to rotate clockwise by the connecting rod, the sliding rod slides in the sliding groove to drive the mounting block to rotate, the blocking block is further driven to rotate, the discharge port of the feeding hopper is opened, the piston rod of the starting cylinder extends out, the discharge port of the feeding hopper is closed, the angle of the blocking block can be adjusted to control the size of the discharge port of the feeding hopper, the entering amount of the molecular sieve can be controlled, the operation is simple, and the device is convenient to use.

3. According to the invention, hot air sucked into the first cavity by the air inlet pipe passes through the dehumidification box, enters the fixed block from the vent groove and then is discharged from the vent groove, the water absorbent absorbs moisture in the hot air, and the hot air with the moisture is prevented from entering the second cavity, so that the drying effect is reduced.

Drawings

FIG. 1 is a schematic sectional view of a molecular sieve forming and drying mechanism according to an embodiment of the present invention;

FIG. 2 is a schematic top view illustrating a molecular sieve forming and drying mechanism according to an embodiment of the present invention;

FIG. 3 is a schematic front view illustrating a first driving mechanism of a molecular sieve forming and drying mechanism according to an embodiment of the present invention;

FIG. 4 is a schematic axial view illustrating a first driving mechanism of a molecular sieve forming and drying mechanism according to an embodiment of the present invention;

FIG. 5 is a schematic axial view illustrating a second driving mechanism of a molecular sieve forming and drying mechanism according to an embodiment of the present invention;

FIG. 6 is a schematic front view illustrating a second driving mechanism of a molecular sieve forming and drying mechanism according to an embodiment of the present invention;

fig. 7 is an enlarged schematic view of a place a of a molecular sieve forming and drying mechanism provided according to an embodiment of the present invention;

fig. 8 shows a schematic view of the inside of a dehumidifying box of a molecular sieve forming and drying mechanism according to an embodiment of the present invention.

Illustration of the drawings:

1. a box body; 101. a first chamber; 102. a second chamber; 2. a feed hopper; 3. a first conveyor belt; 4. a second conveyor belt; 5. a fixing plate; 501. a through groove; 6. a sloping plate; 8. a compression cylinder; 9. an air inlet pipe; 10. an air outlet pipe; 11. a piston; 12. a lifting rod; 13. a moving block; 1301. a groove; 14. an eccentric rod; 15. rotating the disc; 16. a drive motor; 18. heating plates; 20. a hot gas recovery device; 21. installing a box; 22. a one-way valve; 23. a dehumidifying device; 24. a dehumidification box; 25. a fixed block; 2501. mounting grooves; 2502. a vent channel; 26. a water absorbing agent; 27. a central shaft; 28. a plugging block; 29. mounting blocks; 2901. a sliding groove; 30. a slide bar; 31. rotating the block; 32. a connecting rod; 33. and a cylinder.

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.

Examples

Referring to fig. 1-8, the present invention provides a technical solution: a molecular sieve forming and drying mechanism comprises a box body 1, wherein a fixing plate 5 is fixedly installed in the box body 1, the fixing plate 5 divides the box body 1 into a first cavity 101 and a second cavity 102, a first conveying belt 3 is installed in the first cavity 101, a second conveying belt 4 is installed in the second cavity 102, a through groove 501 is formed in the fixing plate 5, an inclined plate 6 is installed at the bottom of the through groove 501, the inclined plate 6 is arranged above the second conveying belt 4, a heating plate 18 is fixedly installed above the first conveying belt 3, and the first conveying belt 3 and the second conveying belt 4 are metal conveying belts; a feeding funnel 2 is fixedly arranged on a box body 1, a control mechanism for changing the size of a discharge hole of the feeding funnel 2 is arranged in the box body 1, a hot gas recovery device 20 is arranged on one side of the box body 1, one end of the hot gas recovery device 20 is communicated with an air inlet pipe 9, the free end of the air inlet pipe 9 is communicated with a first cavity 101, the other end of the hot gas recovery device 20 is communicated with an air outlet pipe 10, the free end of the air outlet pipe 10 is communicated with a second cavity 102, the hot gas recovery device 20 comprises an installation box 21, a compression cylinder 8 is fixedly arranged in the installation box 21, a piston 11 is connected in the compression cylinder 8 in a sliding manner, the bottom of the compression cylinder 8 is communicated with the air inlet pipe 9 and the air outlet pipe 10, a first driving mechanism for driving the piston 11 to reciprocate is arranged in the installation box 21, a one-way valve 22 is arranged in the air inlet pipe 9, a one-way valve 22 is arranged in the air outlet pipe 10, a molecular sieve is poured into the feeding funnel 2, and the molecular sieve falls into a first transmission belt 3, the molecular sieve is conveyed by the first conveying belt 3, the heating plate 18 heats and dries the molecular sieve on the first conveying belt 3, the molecular sieve falls into the through groove 501 from the tail end of the first conveying belt 3, the molecular sieve falls onto the second conveying belt 4 through the inclined plate 6, the driving motor 16 is started, the rotating disc 15 is driven to rotate, the eccentric rod 14 is driven to slide in the groove 1301, the moving block 13 is driven to reciprocate in the vertical direction, the piston 11 is driven to reciprocate in the compression cylinder 8, the piston 11 moves upwards, the compression cylinder 8 sucks hot air in the first cavity 101 through the air inlet pipe 9, the piston 11 moves downwards to discharge the hot air in the compression cylinder 8 into the second cavity 102 through the air outlet pipe 10, the hot air dries the molecular sieve on the second conveying belt 4 for the second time, the hot air is recycled, the resource utilization efficiency is improved, and the energy is saved.

Referring to fig. 2 and 8, the first driving mechanism includes a driving motor 16, a lifting rod 12 is fixedly installed on the top of the piston 11, a moving block 13 is fixedly installed on the top of the lifting rod 12, a groove 1301 is formed in the moving block 13, the driving motor 16 is fixedly installed in the installation box 21, an output shaft of the driving motor 16 is in transmission connection with a rotating disc 15, an eccentric rod 14 sliding in the groove 1301 is fixedly connected to the rotating disc 15, a dehumidifying device 23 is communicated with the middle of the air inlet pipe 9, the dehumidifying device 23 includes a dehumidifying box 24, a plurality of fixing blocks 25 are fixedly installed in the dehumidifying box 24, an installation groove 2501 is formed in the fixing block 25, a water absorbent 26 is filled in the installation groove 2501, a plurality of vent grooves 2502 communicated with the installation groove 2501 are formed in the fixing block 25, the vent grooves 2502 are arranged on the fixing block 25 at equal intervals, the water absorbent 26 is calcium oxide, hot air sucked into the first cavity 101 by the air inlet pipe 9 passes through the dehumidifying box 24, the moisture contained in the hot air is absorbed by the water-absorbing agent 26 discharged from the air channel 2502 after entering the fixing block 25 from the air channel 2502, and the drying effect is deteriorated by preventing the hot air with the moisture from entering the second chamber 102.

Referring to fig. 1-7, the control mechanism includes a blocking block 28, the blocking block 28 is rotatably mounted in the box body 1, the bottom of the blocking block 28 is fixedly connected with an obliquely arranged mounting block 29, a sliding groove 2901 is formed in the mounting block 29, a central shaft 27 is fixedly mounted in the box body 1, a rotating block 31 is rotatably mounted on the central shaft 27, one end of the rotating block 31 is fixedly connected with a sliding rod 30 which slides in the sliding groove 2901, a second driving mechanism which drives the rotating block 31 to rotate is arranged in the box body 1, the sliding rod 30 is welded on the rotating block 31, the second driving mechanism includes an air cylinder 33, a connecting rod 32 is rotatably mounted at the other end of the rotating block 31, the air cylinder 33 is fixedly mounted in the box body 1, a piston rod of the air cylinder 33 is rotatably mounted with a free end of the connecting rod 32, the piston rod of the air cylinder 33 is started to retract, the rotating block 31 is driven to rotate clockwise by the connecting rod 32, the sliding rod 30 slides in the sliding groove 2901 to drive the mounting block 29 to rotate, and then the drive plugging block 28 rotates, opens 2 discharge gates of feed hopper, and in the same way, starts cylinder 33 piston rod and stretches out, closes 2 discharge gates of feed hopper, and the entering amount of molecular sieve can be controlled to 2 discharge gates size of angle control feed hopper of adjustable plugging block 28, easy operation, the use of the device of being convenient for.

The working principle is as follows: the hot air is recycled: firstly, pouring the molecular sieve into a feeding hopper 2, then, falling the molecular sieve onto a first transmission belt 3, transmitting the molecular sieve by the first transmission belt 3, heating the molecular sieve on the first transmission belt 3 by a heating plate 18, falling the molecular sieve into a through groove 501 from the tail end of the first transmission belt 3, falling onto a second transmission belt 4 through an inclined plate 6, then, starting a driving motor 16 to drive a rotating disc 15 to rotate, driving an eccentric rod 14 to slide in a groove 1301, driving a moving block 13 to reciprocate in the vertical direction, further driving a piston 11 to reciprocate in a compression cylinder 8, moving the piston 11 upwards, sucking hot air in a first cavity 101 through an air inlet pipe 9 by the compression cylinder 8, discharging the hot air in the compression cylinder 8 into a second cavity 102 through an air outlet pipe 10 by the piston 11 moving downwards, drying the molecular sieve on the second transmission belt 4 for the second time by the hot air, and further recycling the hot air, the resource utilization efficiency is improved, and energy is saved;

adjusting the size of the discharge hole of the feeding funnel 2: firstly, the piston rod of the starting cylinder 33 retracts, the rotating block 31 is driven to rotate clockwise by the connecting rod 32, the sliding rod 30 slides in the sliding groove 2901 to drive the mounting block 29 to rotate, the sealing block 28 is driven to rotate, the discharge hole of the feeding funnel 2 is opened, similarly, the piston rod of the starting cylinder 33 extends out, the discharge hole of the feeding funnel 2 is closed, the size of the discharge hole of the feeding funnel 2 can be controlled by adjusting the angle of the sealing block 28, the entering amount of the molecular sieve can be controlled, the operation is simple, and the use of the device is convenient;

drying with hot air: the hot air sucked into the first chamber 101 by the air inlet pipe 9 passes through the dehumidifying box 24, enters the fixing block 25 from the air channel 2502 and then is discharged from the air channel 2502, and the water absorbing agent 26 absorbs moisture in the hot air, so that the hot air with the moisture is prevented from entering the second chamber 102, and the drying effect is reduced.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims

1. The molecular sieve forming and drying mechanism comprises a box body (1) and is characterized in that a fixing plate (5) is fixedly mounted in the box body (1), the fixing plate (5) divides the interior of the box body (1) into a first cavity (101) and a second cavity (102), a first transmission belt (3) is mounted in the first cavity (101), a second transmission belt (4) is mounted in the second cavity (102), a through groove (501) is formed in the fixing plate (5), an inclined plate (6) is mounted at the bottom of the through groove (501), the inclined plate (6) is arranged above the second transmission belt (4), and a heating plate (18) is fixedly mounted above the first transmission belt (3);

fixed mounting has feed hopper (2) on box (1), be equipped with the control mechanism who changes feed hopper (2) discharge gate size in box (1), box (1) one side is equipped with steam recovery unit (20), steam recovery unit (20) one end intercommunication has intake pipe (9), the free end and first chamber (101) intercommunication of intake pipe (9), the other end intercommunication of steam recovery unit (20) has outlet duct (10), the free end and the second chamber (102) intercommunication of outlet duct (10).

2. The molecular sieve forming and drying mechanism according to claim 1, wherein the hot gas recovery device (20) comprises an installation box (21), a compression cylinder (8) is fixedly installed in the installation box (21), a piston (11) is slidably connected in the compression cylinder (8), an air inlet pipe (9) and an air outlet pipe (10) are communicated with the bottom of the compression cylinder (8), a first driving mechanism for driving the piston (11) to reciprocate is arranged in the installation box (21), a one-way valve (22) is installed in the air inlet pipe (9), and the one-way valve (22) is installed in the air outlet pipe (10).

3. The molecular sieve forming and drying mechanism according to claim 2, wherein the first driving mechanism comprises a driving motor (16), a lifting rod (12) is fixedly installed at the top of the piston (11), a moving block (13) is fixedly installed at the top of the lifting rod (12), a groove (1301) is formed in the moving block (13), the driving motor (16) is fixedly installed in the installation box (21), a rotating disc (15) is connected to an output shaft of the driving motor (16) in a transmission manner, and an eccentric rod (14) which slides in the groove (1301) is fixedly connected to the rotating disc (15).

4. The molecular sieve forming and drying mechanism according to claim 2, wherein a dehumidifying device (23) is communicated with the middle of the air inlet pipe (9), the dehumidifying device (23) comprises a dehumidifying box (24), a plurality of fixing blocks (25) are fixedly mounted in the dehumidifying box (24), an installation groove (2501) is formed in each fixing block (25), a water absorbing agent (26) is filled in each installation groove (2501), and a plurality of vent grooves (2502) communicated with the installation grooves (2501) are formed in each fixing block (25).

5. The molecular sieve forming and drying mechanism according to claim 4, wherein a plurality of said ventilation slots (2502) are arranged at equal intervals on the fixed block (25).

6. The molecular sieve forming and drying mechanism according to claim 1, wherein the first conveyor belt (3) and the second conveyor belt (4) are metal conveyor belts.

7. The molecular sieve forming and drying mechanism according to claim 1, wherein the control mechanism comprises a blocking block (28), the blocking block (28) is rotatably mounted in the box body (1), a mounting block (29) which is obliquely arranged is fixedly connected to the bottom of the blocking block (28), a sliding groove (2901) is formed in the mounting block (29), a central shaft (27) is fixedly mounted in the box body (1), a rotating block (31) is rotatably mounted on the central shaft (27), a sliding rod (30) which slides in the sliding groove (2901) is fixedly connected to one end of the rotating block (31), and a second driving mechanism which drives the rotating block (31) to rotate is arranged in the box body (1).

8. The molecular sieve forming and drying mechanism according to claim 4, wherein the water absorbent (26) is calcium oxide.

9. The molecular sieve forming and drying mechanism according to claim 7, wherein the second driving mechanism comprises a cylinder (33), a connecting rod (32) is rotatably mounted at the other end of the rotating block (31), the cylinder (33) is fixedly mounted in the box body (1), and a piston rod of the cylinder (33) is rotatably mounted with a free end of the connecting rod (32).

10. The molecular sieve forming and drying mechanism according to claim 7, wherein the sliding rod (30) is welded on the rotating block (31).