CN212457795U

CN212457795U - Catalyst drying line

Info

Publication number: CN212457795U
Application number: CN202020992671.1U
Authority: CN
Inventors: 王杰; 邓立锋; 刘安阳; 陈春兴; 何伟
Original assignee: Jiangsu Longjing Kejie Environmental Protection Technology Co ltd
Current assignee: Jiangsu Longjing Kejie Environmental Protection Technology Co ltd
Priority date: 2020-06-03
Filing date: 2020-06-03
Publication date: 2021-02-02
Anticipated expiration: 2030-06-03

Abstract

The utility model discloses a catalyst stoving line, include: a bin body; the lower transportation unit is arranged in the bin body; the upper transportation unit is arranged in the bin body and is positioned above the lower transportation unit, and the transportation direction of the upper transportation unit is opposite to that of the lower transportation unit; the lifting unit is arranged in the bin body and is close to the discharge end of the lower conveying unit and the feeding end of the upper conveying unit; and the drying and heating units are respectively arranged above the lower conveying unit and the upper conveying unit. Transport unit and last transport unit folding connection in the storehouse internal down, reduced stoving line length, can not seriously occupy factory building area, transport unit feed end down, transport unit discharge end on and all be located the storehouse external, only need a station like this, just can accomplish and go up unloading, saved the manpower.

Description

Catalyst drying line

Technical Field

The utility model relates to a catalyst stoving technical field, specifically speaking relates to a catalyst stoving line.

Background

The existing catalyst drying line is one hundred meters long in total, the front side is used for loading materials, the rear side is used for unloading materials, two stations are used, two workers are required to work simultaneously, manpower is wasted, and the length of the drying line is too long, so that the factory area is seriously occupied.

SUMMERY OF THE UTILITY MODEL

In order to achieve the above object, the utility model discloses a catalyst stoving line, include:

a bin body;

the lower transportation unit is arranged in the bin body;

the upper transportation unit is arranged in the bin body and is positioned above the lower transportation unit, and the transportation direction of the upper transportation unit is opposite to that of the lower transportation unit;

the lifting unit is arranged in the bin body and is close to the discharge end of the lower conveying unit and the feeding end of the upper conveying unit;

and the drying and heating units are respectively arranged above the lower conveying unit and the upper conveying unit.

Preferably, the feeding end of the lower conveying unit and the discharging end of the upper conveying unit extend out of the bin body.

Preferably, a heat preservation layer is laid on the inner wall of the bin body, and a wind conveying motor is installed at the top end of the bin body.

Preferably, the method further comprises the following steps:

the temperature sensors are arranged in the bin body and are respectively positioned between the lower conveying unit and the drying and heating unit and between the upper conveying unit and the drying and heating unit;

and the processor is connected with the temperature sensor, the drying and heating unit, the lower conveying unit and the upper conveying unit.

Preferably, the lower transport unit includes:

the drying and heating unit is arranged on the rack;

the net chain belt is positioned in the rack;

the driving roller and the driven roller are connected to the rack, and the net chain belt is sleeved on the driving roller and the driven roller;

the driving motor is connected in the rack, the output end of the driving motor is connected with the driving roller, and the driving motor is connected with the processor;

the net chain belt supporting plate is connected in the rack and is arranged close to the top end in the net chain belt.

Preferably, the upper transport unit includes:

the drying and heating unit is arranged on the rack;

the net chain belt is positioned in the rack;

Preferably, the lifting unit includes:

a hydraulic lifting platform;

the rotating seat is connected to the hydraulic lifting platform;

the conveyer is arranged on the rotating seat;

and the position sensor is arranged on the conveyor, and the position sensor, the conveyor and the hydraulic lifting platform are all connected with the processor.

Preferably, the hydraulic lifting platform comprises:

the rotating seat is connected to the mounting seat;

the support device comprises a first support rod and a second support rod, wherein the first support rod and the second support rod are arranged between a base and an installation seat in a scissor-fork type manner, one end of the first support rod is rotatably connected with the top end of the base, the other end of the first support rod is slidably connected with the bottom end of the installation seat, one end of the second support rod is slidably connected with the top end of the base, and the other end of the second support rod is rotatably connected with the bottom end of the installation seat;

and one end of the hydraulic cylinder is connected with the first supporting rod, the other end of the hydraulic cylinder is connected with the second supporting rod, and the hydraulic cylinder is connected with the processor.

Preferably, the rotary seat includes:

the mounting chamber is embedded in the mounting seat, the bottom end of the mounting chamber and the bottom end of the mounting seat are arranged in a coplanar manner, and an opening is formed in the bottom end of the mounting chamber;

the rotating chamber is arranged in the mounting seat and is positioned above the mounting chamber;

the fixed circular groove is formed in the top end of the mounting seat and is positioned above the rotating chamber;

the rotary circular table is rotatably connected into the fixed circular groove, and the conveyor is connected onto the rotary circular table;

the rotating shaft is connected to the bottom end of the rotating circular platform, and the end, far away from the rotating circular platform, of the rotating shaft is respectively arranged in the rotating chamber and the mounting chamber in a penetrating mode;

the first bevel gear is arranged in the rotating chamber and connected to the rotating shaft;

the rotating motor is arranged in the rotating chamber;

the second bevel gear is connected to the output end of the rotating motor and meshed with the first bevel gear;

the rotary inclined plate is hinged to the opening, a reset coil spring is connected to the hinged end of the rotary inclined plate, and the high-level end of the rotary inclined plate is arranged close to the center end of the mounting seat;

the fixed transverse plate is arranged in the mounting chamber and connected to the bottom end of the rotating shaft;

the two T-shaped grooves are symmetrically connected to the bottom end of the fixed transverse plate by taking the rotating shaft as the center;

the sliding blocks are arranged in the T-shaped grooves in equal quantity and are connected in the T-shaped grooves in a sliding mode;

the reset spring is arranged in the T-shaped groove, one end of the reset spring is connected with the T-shaped groove, and the other end of the reset spring is connected with the sliding block;

the lifting block is arranged in the installation chamber and is arranged close to the inclined rotating plate;

the support arm, two the support arm is the V font and articulates on the elevator, the support arm is kept away from the elevator end and is worn to establish T type groove and sliding block rotation and be connected.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the embodiments or the technical solutions in the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

FIG. 1 is a schematic structural view of the present invention;

fig. 2 is a side view of the present invention;

FIG. 3 is a control schematic diagram of the present invention;

fig. 4 is a schematic structural view of the hydraulic lifting platform of the present invention;

fig. 5 is a schematic view of the structure of the rotary seat of the present invention.

In the figure: 1. a bin body; 2. a lower transport unit; 3. an upper transport unit; 4. a lifting unit; 5. a drying and heating unit; 6, insulating layer; 7. a wind motor; 8. a processor; 41. a hydraulic lifting platform; 42. a rotating seat; 43. a conveyor; 45. a first support bar; 46. a second support bar; 47. a hydraulic cylinder; 421. an installation chamber; 422. a rotating chamber; 423. fixing the circular groove; 424. rotating the circular truncated cone; 425. a rotating shaft; 426. a first bevel gear; 427. rotating the motor; 428. a second bevel gear; 429. rotating the inclined plate; 481. fixing the transverse plate; 482. T-groove; 483. a slider; 484. a return spring; 485, a lifting block; 486. and (4) a support arm.

Detailed Description

The technical solution of the present invention will be described clearly and completely with reference to the accompanying drawings, and obviously, the described embodiments are some, but not all embodiments of the present invention. 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.

Examples

The present invention will be further described with reference to the accompanying drawings.

As shown in fig. 1, the catalyst drying line provided in this embodiment includes:

a bin body 1;

the lower conveying unit 2 is arranged in the bin body 1;

the upper conveying unit 3 is arranged in the bin body 1 and is positioned above the lower conveying unit 2, and the conveying direction of the upper conveying unit 3 is opposite to that of the lower conveying unit 2;

the lifting unit 4 is arranged in the bin body 1, and the lifting unit 4 is arranged close to the discharge end of the lower conveying unit 2 and the feeding end of the upper conveying unit 3;

and the drying and heating units 5 are arranged above the lower conveying unit 2 and above the upper conveying unit 3 respectively.

The working principle and the beneficial effects of the technical scheme are as follows:

the utility model discloses a catalyst drying line, which adopts a lower transportation unit 2 and an upper transportation unit 3, the lower transportation unit 2 and the upper transportation unit 3 are connected in a folding way in a bin body 1, the drying line length is reduced, the factory area is not seriously occupied, a plurality of drying and heating units 5 are respectively arranged above the lower transportation unit 2 and above the upper transportation unit 3, the catalyst is dried, the catalyst is sent into the bin body 1 from the feeding end of the lower transportation unit 2 and moves onto a lifting unit 4 from the discharging end of the lower transportation unit 2, the lifting unit 4 is lifted to lift the catalyst to be close to the feeding end of the upper transportation unit 3, the catalyst moves to the outside of the bin body 1 from the discharging end of the upper transportation unit 3, the feeding end of the lower transportation unit 2 and the discharging end of the upper transportation unit 3 are both positioned outside the bin body 1, thus, only one station is needed, and the operation can be completed, the manpower is saved.

In one embodiment, the feeding end of the lower transporting unit 2 and the discharging end of the upper transporting unit 3 extend out of the bin body 1.

In one embodiment, as shown in fig. 2, an insulating layer 6 is laid on the inner wall of the bin body 1, and a wind conveying motor 7 is mounted at the top end of the bin body 1.

the heat preservation layer 6 prevents the heat loss in the bin body 1, and the air conveying motor 7 enables the heat generated by the drying and heating unit 5 to be uniformly dispersed in the bin body 1.

As shown in fig. 3, in one embodiment, the method further includes:

the temperature sensors are arranged in the bin body 1 and are respectively positioned between the lower conveying unit 2 and the drying and heating unit 5 and between the upper conveying unit 3 and the drying and heating unit 5;

and the processor 8, wherein the processor 8 is connected with the temperature sensor, the drying and heating unit 5, the lower conveying unit 2 and the upper conveying unit 3.

the temperature sensor is used for monitoring the temperature in the bin body 1, and when the temperature is too high or too low, the power of the drying and heating unit 5 is reduced or increased through the processor 8.

In one embodiment, the lower transport unit 2 comprises:

the drying and heating unit 5 is arranged on the rack;

the net chain belt is positioned in the rack;

the driving motor is connected in the rack, the output end of the driving motor is connected with the driving roller, and the driving motor is connected with the processor 8;

In one embodiment, the upper transport unit 3 comprises:

the drying and heating unit 5 is arranged on the rack;

the net chain belt is positioned in the rack;

As shown in fig. 4, in one embodiment, the lifting unit 4 includes:

a hydraulic lifting platform 41;

the rotating seat 42 is connected to the hydraulic lifting platform 41;

a conveyor 43, wherein the conveyor 43 is mounted on the rotating base 42;

and the position sensor is arranged on the conveyor 43, and the position sensor, the conveyor 43 and the hydraulic lifting platform 41 are all connected with the processor 8.

the position sensor is used for detecting whether the catalyst moves to the lifting unit 4 or not, the conveyor 43 conveys the catalyst from the discharge end of the lower conveying unit 2 to the lifting unit 4, when the position sensor detects a position signal of the catalyst, the position signal is sent to the processor 8, the processor 8 sends a work stopping instruction to the lower conveying unit 2 and a work instruction to the hydraulic lifting platform 41 respectively, when the hydraulic lifting platform 41 moves to be level with the upper conveying unit 3, the rotating seat 42 works, the conveyor 43 rotates 180 degrees, the conveyor 43 works, and the catalyst is moved away from the material conveying end of the upper conveying unit 3 from the lifting unit 4.

In one embodiment, the hydraulic lift platform 41 comprises:

the rotating seat is connected to the mounting seat;

the support device comprises a first support rod 45 and a second support rod 46, wherein the first support rod 45 and the second support rod 46 are arranged between a base and a mounting seat in a scissor-fork type manner, one end of the first support rod 45 is rotatably connected with the top end of the base, the other end of the first support rod 45 is slidably connected with the bottom end of the mounting seat, one end of the second support rod 46 is slidably connected with the top end of the base, and the other end of the second support rod 46 is rotatably connected with the bottom end of the mounting seat;

and one end of the hydraulic cylinder 47 is connected with the first supporting rod 45, the other end of the hydraulic cylinder 47 is connected with the second supporting rod 46, and the hydraulic cylinder 47 is connected with the processor 8.

the hydraulic cylinder 47 is contracted, so that the bottom end of the first support rod 45 and the bottom end of the second support rod 46 are close to each other, the bottom end of the second support rod 46 slides towards the first support rod 45, the top end of the first support rod 45 slides towards the second support rod 46, and the mounting seat is lifted.

As shown in fig. 5, in one embodiment, the rotating base 42 includes:

the mounting chamber 421 is embedded in the mounting seat, the bottom end of the mounting chamber 421 and the bottom end of the mounting seat are arranged in a coplanar manner, and the bottom end of the mounting chamber 421 is provided with an opening 420;

the rotating chamber 422 is arranged in the mounting seat, and the rotating chamber 422 is positioned above the mounting chamber 421;

the fixed circular groove 423 is formed in the top end of the mounting seat, and the fixed circular groove 423 is located above the rotating chamber 422;

the rotary round table 424, the rotary round table 424 is rotatably connected in the fixed round groove 423, and the conveyor 43 is connected to the rotary round table 424;

the rotating shaft 425 is connected to the bottom end of the rotating round table 424, and the end, away from the rotating round table 424, of the rotating shaft 425 penetrates through the rotating chamber 422 and the mounting chamber 421;

a first bevel gear 426, wherein the first bevel gear 426 is arranged in the rotating chamber 422, and the first bevel gear 426 is connected to the rotating shaft 425;

a rotating motor 427, the rotating motor 427 being provided in the rotating chamber 422;

a second bevel gear 428, wherein the second bevel gear 428 is connected to the output end of the rotating motor 427, and the second bevel gear 428 is meshed with the first bevel gear 426;

the rotary inclined plate 429 is hinged to the opening 420, a reset coil spring is connected to the hinged end of the rotary inclined plate 429, and the high-level end of the rotary inclined plate 429 is arranged close to the center end of the mounting seat;

a fixed transverse plate 481, the fixed transverse plate 481 is arranged in the installation chamber 421, and the fixed transverse plate 481 is connected with the bottom end of the rotating shaft 425;

the two T-shaped grooves 482 are symmetrically connected to the bottom end of the fixed transverse plate 481 by taking the rotating shaft 425 as a center;

sliding blocks 483, wherein the sliding blocks 483 are arranged in the T-shaped groove 482 in equal number, and the sliding blocks 483 are connected in the T-shaped groove 482 in a sliding manner;

a return spring 484, wherein the return spring 484 is arranged in the T-shaped groove 482, one end of the return spring 484 is connected with the T-shaped groove 482, and the other end of the return spring 484 is connected with the sliding block 483;

the lifting block 485 is arranged in the installation chamber 421 and is arranged close to the inclined rotating plate 429;

and the support arms 486 are hinged on the lifting block 485 in a V shape, and the end, far away from the lifting block 485, of the support arm 486 is penetrated with the T-shaped groove 482 and is rotationally connected with the sliding block 483.

when the top end of the first supporting rod 45 slides to the position of the inclined rotating plate 429 at the bottom end of the mounting seat, the inclined rotating plate 429 gradually tends to be coplanar with the bottom end of the mounting chamber 421, at this time, the rotating motor 427 located in the rotating chamber 422 drives the conveyor 43 connected with the rotating table 424 to rotate through the second bevel gear 428 connected to the output end of the rotating motor 427, the first bevel gear 426 meshed with the second bevel gear 428, the rotating shaft 425 connected with the first bevel gear 426, the rotating table 424 connected with the rotating shaft 425, and after the conveyor 43 completes 180 degrees of rotation, at this time, the first supporting rod 45 slides right onto the inclined rotating plate 429, the inclined rotating plate 429 is coplanar with the bottom end of the mounting chamber 421, the inclined rotating plate 429 presses the lifting block 485 to move towards the fixed plate 481, so that the included angle between the two supporting arm transverse plates 486 is widened, the return spring 484 lengthens in the T-shaped groove 482, and the sliding block 482 connected with the end of the supporting arm 486 far from the lifting block 485 moves, the end of the sliding block 483 far away from the return spring 484 is clamped on the inner wall of the installation chamber 421, so that the rotating shaft 425 stops rotating, when the installation seat descends, the top end of the first supporting rod 45 slides in the direction far away from the rotating inclined plate 429, at the moment, the rotating inclined plate 429 loses the acting force of the first supporting plate 45, the rotating inclined plate 429 recovers to the original state under the action of the return spring and the return coil spring, the included angle of the two supporting arms 486 is reduced, the end of the sliding block 483 far away from the return spring 484 releases the clamping on the inner wall of the installation chamber 421, the rotating shaft 425 recovers to rotate, the rotating motor 427 drives the conveyor 43 to rotate 180 degrees again, and at the moment, the installation seat descends to the position of the lower.

It should be understood that the above examples are only for clarity of illustration and are not intended to limit the embodiments. Other variations and modifications will be apparent to persons skilled in the art in light of the above description. And are neither required nor exhaustive of all embodiments. And obvious variations or modifications can be made without departing from the scope of the invention.

Claims

1. A catalyst drying line, comprising:

a cabin body (1);

the lower conveying unit (2), the lower conveying unit (2) is arranged in the bin body (1);

the upper conveying unit (3) is arranged in the bin body (1) and is positioned above the lower conveying unit (2), and the conveying direction of the upper conveying unit (3) is opposite to that of the lower conveying unit (2);

the lifting unit (4) is arranged in the bin body (1), and the lifting unit (4) is arranged close to the discharge end of the lower conveying unit (2) and the feeding end of the upper conveying unit (3);

and the drying and heating units (5) are respectively arranged above the lower conveying unit (2) and above the upper conveying unit (3).

2. The catalyst drying line according to claim 1, wherein the feeding end of the lower conveying unit (2) and the discharging end of the upper conveying unit (3) extend out of the bin body (1).

3. The catalyst drying line according to claim 1, wherein an insulating layer (6) is laid on the inner wall of the bin body (1), and a wind conveying motor (7) is installed at the top end of the bin body (1).

4. A catalyst drying line according to claim 1, further comprising:

the temperature sensors are arranged in the bin body (1) and are respectively positioned between the lower conveying unit (2) and the drying and heating unit (5) and between the upper conveying unit (3) and the drying and heating unit (5);

and the processor (8), the processor (8) is connected with the temperature sensor, the drying and heating unit (5), the lower conveying unit (2) and the upper conveying unit (3).

5. A catalyst drying line according to claim 1, characterized in that said lower transport unit (2) comprises:

the drying and heating unit (5) is arranged on the rack;

the net chain belt is positioned in the rack;

the driving motor is connected in the rack, the output end of the driving motor is connected with the driving roller, and the driving motor is connected with the processor (8);

6. A catalyst drying line according to claim 1, characterized in that said upper transport unit (3) comprises:

the drying and heating unit (5) is arranged on the rack;

the net chain belt is positioned in the rack;

7. A catalyst drying line according to claim 1, characterized in that said lifting unit (4) comprises:

a hydraulic lifting platform (41);

the rotating seat (42), the rotating seat (42) is connected to the hydraulic lifting platform (41);

a conveyor (43), wherein the conveyor (43) is mounted on the rotating base (42);

the position sensor is installed on the conveyor (43), and the position sensor, the conveyor (43) and the hydraulic lifting platform (41) are all connected with the processor (8).

8. A catalyst drying line according to claim 7, characterized in that the hydraulic lifting platform (41) comprises:

the rotating seat is connected to the mounting seat;

the supporting device comprises a first supporting rod (45) and a second supporting rod (46), wherein the first supporting rod (45) and the second supporting rod (46) are arranged between a base and an installation seat in a scissor-fork type mode, one end of the first supporting rod (45) is rotatably connected with the top end of the base, the other end of the first supporting rod (45) is slidably connected with the bottom end of the installation seat, one end of the second supporting rod (46) is slidably connected with the top end of the base, and the other end of the second supporting rod (46) is rotatably connected with the bottom end of the installation seat;

pneumatic cylinder (47), pneumatic cylinder (47) one end is connected with first bracing piece (45), pneumatic cylinder (47) other end is connected with second bracing piece (46), pneumatic cylinder (47) are connected with treater (8).

9. A catalyst drying line according to claim 8, characterised in that said rotary seat (42) comprises:

the mounting chamber (421) is embedded in the mounting seat, the bottom end of the mounting chamber (421) and the bottom end of the mounting seat are arranged in a coplanar manner, and the bottom end of the mounting chamber (421) is provided with an opening (420);

the rotating chamber (422) is arranged in the mounting seat, and the rotating chamber (422) is positioned above the mounting chamber (421);

the fixing circular groove (423) is formed in the top end of the mounting seat, and the fixing circular groove (423) is located above the rotating chamber (422);

the rotary round table (424), the rotary round table (424) is rotatably connected in the fixed round groove (423), and the conveyor (43) is connected to the rotary round table (424);

the rotating shaft (425), the rotating shaft (425) is connected to the bottom end of the rotating circular truncated cone (424), and the end, far away from the rotating circular truncated cone (424), of the rotating shaft (425) penetrates through the rotating chamber (422) and the mounting chamber (421) respectively;

the first bevel gear (426), the first bevel gear (426) is arranged in the rotating chamber (422), and the first bevel gear (426) is connected to the rotating shaft (425);

a rotating motor (427), wherein the rotating motor (427) is arranged in the rotating chamber (422), and the rotating motor (427) is connected with the processor (8);

a second bevel gear (428), the second bevel gear (428) is connected with the output end of the rotating motor (427), and the second bevel gear (428) is meshed with the first bevel gear (426);

the rotary sloping plate (429), the rotary sloping plate (429) is hinged to the opening (420), the hinged end of the rotary sloping plate (429) is connected with a reset coil spring, and the high-level end of the rotary sloping plate (429) is arranged close to the center end of the mounting seat;

the fixing transverse plate (481) is arranged in the mounting chamber (421), and the fixing transverse plate (481) is connected to the bottom end of the rotating shaft (425);

the two T-shaped grooves (482) are symmetrically connected to the bottom end of the fixed transverse plate (481) by taking the rotating shaft (425) as a center;

sliding blocks (483), the sliding blocks (483) are arranged in the T-shaped groove (482) in equal number, and the sliding blocks (483) are connected in the T-shaped groove (482) in a sliding mode;

the return spring (484), the return spring (484) is arranged in the T-shaped groove (482), one end of the return spring (484) is connected with the T-shaped groove (482), and the other end of the return spring (484) is connected with the sliding block (483);

the lifting block (485) is arranged in the mounting chamber (421) and is close to the rotating inclined plate (429);

and the support arms (486) are hinged on the lifting block (485) in a V shape, and the end, far away from the lifting block (485), of the support arm (486) penetrates through the T-shaped groove (482) to be rotatably connected with the sliding block (483).