CN111121411A - Active carbon fiber dewatering system - Google Patents

Abstract

The invention discloses an active carbon fiber dehydration system, which belongs to the technical field of carbon fiber production equipment and comprises a base and support plates arranged on two sides of the top of the base, wherein the top of each support plate is fixedly connected with a positioning plate, one end of each positioning plate is fixedly provided with a support rod, a rotating frame is fixedly arranged between the two support rods, a drying box is fixedly arranged between the two support plates, a dehydration device is arranged below the drying box, and the dehydration device comprises a first extrusion roller and a second extrusion roller arranged below the first extrusion roller. According to the invention, most of water in the carbon fiber felt can be extruded out by the dewatering device, and meanwhile, the drying box is arranged to enable the carbon fiber felt to enter the condensing box for quick freezing and then enter the sublimation box for sublimation, and finally enter the cooling box for cooling and then enter the rotating frame for rotating and airing, so that natural airing is not required, and meanwhile, the felt does not need to be moved into drying equipment for drying, so that the time is saved, and the production efficiency is improved.

Description

Active carbon fiber dewatering system

Technical Field

The invention relates to a dehydration system, in particular to an active carbon fiber dehydration system, and belongs to the technical field of carbon fiber production equipment.

Background

The activated carbon fiber is a novel, efficient and multifunctional adsorbing material developed in the 70 th of the 20 th century, and is a third-generation product after powdered activated carbon and granular activated carbon. The activated carbon fiber has a large specific surface area and rich micropores, and the volume of the micropores accounts for more than 90% of the total pore volume. The activated carbon fiber has larger adsorption capacity and faster adsorption dynamic performance than granular activated carbon, has high adsorption efficiency on organic matters, anions and cations in liquid phase and gas phase, has high adsorption and desorption speeds, can be regenerated and recycled, is acid-resistant, alkali-resistant, high-temperature-resistant, strong in adaptability and good in conductivity and chemical stability, and is an ideal environment-friendly material.

After the existing activated carbon fiber pretreatment process, a carbon fiber felt is put into a dehydration system for dehydration and then is aired or dried, a large amount of water is remained in the simple dehydrated carbon fiber felt and is aired only by consuming a large amount of time, or the drying system is adopted for drying, so that the larger felt needs to be manually submitted to move, and meanwhile, one process is added, and the production efficiency is seriously influenced.

Disclosure of Invention

The main purpose of the present invention is to provide a dewatering system for activated carbon fibers, which solves the disadvantages of the prior art.

The purpose of the invention can be achieved by adopting the following technical scheme:

an active carbon fiber dewatering system comprises a base and supporting plates arranged on two sides of the top of the base, wherein a positioning plate is fixedly connected to the top of the supporting plate, supporting rods are fixedly arranged at one end of the positioning plate, a rotating frame is fixedly arranged between the two supporting rods, a drying box is fixedly arranged between the two supporting plates, a dewatering device is arranged below the drying box, the dewatering device comprises a first squeeze roller and a second squeeze roller arranged below the first squeeze roller, a guide shaft is arranged on one side of the second squeeze roller, driven gears are arranged at the first squeeze roller, the second squeeze roller and one end of the guide shaft, a supporting table is arranged above the drying box, a second motor is fixedly arranged at the top of the supporting table, the output end of the second motor is connected with a driving gear, and the driving gear is connected with the driven gears through a chain, the drying box comprises a second drying device, a transition box and a second drying device, wherein the transition box and the second drying device are sequentially arranged above the second drying device from bottom to top, the second drying device comprises a microwave box, and a first guide plate, a second guide plate and a third guide plate which are arranged inside the microwave box and are distributed in a staggered mode, magnetrons are respectively arranged on two sides of the first guide plate, and a flow-resisting box is arranged below the microwave box.

Preferably, a wavy flow resisting plate is arranged in the flow resisting box, and one side of the flow resisting plate is provided with a flow resisting plate communicated with the microwave box.

Preferably, the second drying device includes the condensing box and follows supreme installing in proper order down the sublimation case and the cooler bin of condensing box top, the both ends of condensing box inside all are equipped with the condenser pipe, the inside of sublimating the case is equipped with a plurality of heating wires, second drying device's outer wall has been seted up and has been used for sublime the ventilative gas outlet of case, the inside of cooler bin is equipped with a plurality of evenly distributed's circulating fan.

Preferably, the condensing box with the inside of subliming the case all is equipped with temperature sensor, the export has all been seted up to the inside of condensing box, subliming case and cooler bin.

Preferably, a nitrogen box is arranged below the drying box, an air pump is arranged inside the nitrogen box, and the output end of the air pump is communicated with the second drying device through an air conveying pipe.

Preferably, the swivel mount includes the support frame and installs the second backing roll at support frame both ends, fixed mounting has first motor on the support rod, the first backing roll of output fixedly connected with of first motor, the other end movable mounting of first backing roll is in on the support frame.

Preferably, a driven gear is obliquely installed below the supporting rod, one end of each inclined rod is fixedly installed on the supporting rod, the other end of each inclined rod is fixedly installed on the positioning plate, and a third supporting roller and a fourth supporting roller are fixedly installed between the two inclined rods.

Preferably, the first guide plate, the second guide plate and the third guide plate are all hollow guide plates.

Preferably, the base is provided with an operation panel matched with the drying box.

The invention has the beneficial technical effects that: according to the active carbon fiber dewatering system, the dewatering device is arranged to extrude most of water in the carbon fiber felt, the drying box is arranged to enable the carbon fiber felt to enter the condensing box for quick freezing and then enter the sublimation box for sublimation, and finally enter the cooling box for cooling and then enter the rotating frame for rotating and airing, natural airing is not needed, meanwhile, the felt does not need to be moved into drying equipment for drying, time is saved, and production efficiency is improved.

Drawings

FIG. 1 is a perspective view showing the overall structure of a preferred embodiment of a system for dehydrating activated carbon fibers according to the present invention;

FIG. 2 is a rear view of the overall construction of a preferred embodiment of an activated carbon fiber dewatering system according to the present invention;

FIG. 3 is a schematic view showing the structure of a second drying device in accordance with a preferred embodiment of the dewatering system for activated carbon fiber according to the present invention;

FIG. 4 is a schematic structural view of a drying box of a preferred embodiment of the dewatering system for activated carbon fibers according to the present invention;

FIG. 5 is a left side view showing the structure of a second drying device in accordance with a preferred embodiment of the dewatering system for activated carbon fiber according to the present invention;

fig. 6 is a schematic perspective view illustrating a second drying device in accordance with a preferred embodiment of the dewatering system for activated carbon fiber according to the present invention.

In the figure: 1-a base, 2-a dehydration device, 3-a drying box, 4-a positioning plate, 5-a supporting plate, 6-a rotating frame, 7-a supporting frame, 8-a first supporting roller, 9-a second supporting roller, 10-a third supporting roller, 11-a fourth supporting roller, 12-a first motor, 13-a first squeezing roller, 14-a second squeezing roller, 15-a driven gear, 16-a chain, 17-a second motor, 18-a guiding shaft, 19-a supporting rod, 20-a feeding port, 21-a flow resisting plate, 22-a flow resisting box, 23-a first guiding plate, 24-a second guiding plate, 25-a magnetron, 26-a third guiding plate, 27-a condensing box, 28-a sublimation box, 29-a cooling box and 30-a temperature sensor, 31-a condensation pipe, 32-an electric heating wire, 33-a circulating fan, 34-an outlet, 35-a nitrogen box, 36-an air pump, 37-an air pipe, 38-a second drying device, 39-a transition box, 40-the second drying device, 41-an air outlet, 42-a support table, 43-a driving gear, 44-a microwave box, 45-an inclined rod and 46-an operation panel.

Detailed Description

In order to make the technical solutions of the present invention more clear and definite for those skilled in the art, the present invention is further described in detail below with reference to the examples and the accompanying drawings, but the embodiments of the present invention are not limited thereto.

As shown in fig. 1-6, the activated carbon fiber dewatering system provided in this embodiment includes a base 1 and support plates 5 installed on two sides of the top of the base 1, a positioning plate 4 is fixedly connected to the top of the support plate 5, a support rod 19 is fixedly installed at one end of the positioning plate 4, a rotating frame 6 is fixedly installed between the two support rods 19, a drying oven 3 is fixedly installed between the two support plates 5, a dewatering device 2 is installed below the drying oven 3, the dewatering device 2 includes a first squeeze roller 13 and a second squeeze roller 14 installed below the first squeeze roller 13, a guide shaft 18 is installed at one side of the second squeeze roller 14, driven gears 15 are installed at one ends of the first squeeze roller 13, the second squeeze roller 14 and the guide shaft 18, a support table 42 is installed above the drying oven 3, a second motor 17 is fixedly installed at the top of the support table 42, and an output end of the second motor 17 is connected to, the driving gear 43 is connected with a plurality of driven gears 15 through a chain 16, the drying box 3 comprises a second drying device 38, and a transition box 39 and a second drying device 40 which are sequentially arranged above the second drying device 38 from bottom to top, the second drying device 38 comprises a microwave box 44, and a first guide plate 23, a second guide plate 24 and a third guide plate 26 which are arranged inside the microwave box 44 and are in staggered distribution, two sides of the first guide plate 23 are respectively provided with a magnetron 25, and a choke box 22 is arranged below the microwave box 44. This active carbon fiber dewatering system is equipped with dewatering device 2 and can goes out the inside most water extrusion of carbon fiber felt, is equipped with simultaneously that drying cabinet 3 can get into the inside sublimation of sublimation case 28 after getting into the condenser box 27 quick freezing earlier with the carbon fiber felt, gets into 6 internal rotation sunning of swivel mount after the cooling of cooler bin 29 at last, need not to carry out natural sunning, also need not to dry in the immigration drying equipment of felt simultaneously, save time improves production efficiency.

In the present embodiment, as shown in fig. 1 and 3, a wave-shaped current-resisting plate 21 is provided in the current-resisting box 22, and one side of the current-resisting plate 21 is provided with the current-resisting plate 21 penetrating the microwave box 44. Second drying device 40 includes condensing box 27 and follows supreme sublimation case 28 and the cooler bin 29 of installing in proper order in the condensing box 27 top down, and the both ends of condensing box 27 inside all are equipped with condenser pipe 31, and the inside of subliming case 28 is equipped with a plurality of heating wires 32, and second drying device 40's outer wall is offered and is used for subliming the ventilative gas outlet 41 of case 28, and the inside of cooler bin 29 is equipped with a plurality of evenly distributed's circulating fan 33. The inside of condensing box 27 and sublimation case 28 all is equipped with temperature sensor 30, and export 34 has all been seted up to the inside of condensing box 27, sublimation case 28 and cooler bin 29. A nitrogen box 35 is arranged below the drying box 3, an air pump 36 is arranged inside the nitrogen box 35, and the output end of the air pump 36 is communicated with a second drying device 38 through an air conveying pipe 37. This active carbon fiber dewatering system is equipped with condensing box 27 and is equipped with condenser pipe 31 in the inside of condensing box 27 and can carry out quick freezing with guaranteeing the dry remaining moisture of microwave box 44, and it is inconvenient to guarantee the original inside microporous structure of carbon fiber felt, utilize simultaneously that sublimation box 28 is inside heating wire 32 to sublime the carbon fiber felt, make the direct sublimation of frozen hydrone become vapor and escape, the concentrated phenomenon can not take place because of the dehydration in the sublimation process, avoided producing the foam by vapor, side effects such as oxidation. The activated carbon fiber dehydration system is provided with a temperature sensor 30 capable of constantly detecting the temperature of the condensation tank 27 and the sublimation tank 28 and transmitting the temperature to the operation panel 46 for constantly controlling the temperature change.

In this embodiment, as shown in fig. 1 and 5, the rotating frame 6 includes a supporting frame 7 and second supporting rollers 9 installed at two ends of the supporting frame 7, a first motor 12 is fixedly installed on a supporting rod 19, a first supporting roller 8 is fixedly connected to an output end of the first motor 12, and the other end of the first supporting roller 8 is movably installed on the supporting frame 7. The driven gear 15 is obliquely arranged below the supporting rod 19, one end of the oblique rod 45 is fixedly arranged on the supporting rod 19, the other end of the oblique rod 45 is fixedly arranged on the positioning plate 4, and the third supporting roller 10 and the fourth supporting roller 11 are fixedly arranged between the two oblique rods 45. The first guide plate 23, the second guide plate 24 and the third guide plate 26 are all hollow guide plates. The base 1 is provided with an operation panel 46 which is engaged with the drying box 3. The active carbon fiber dewatering system is provided with the support frame 7, so that the carbon fiber felt can be cooled conveniently, the felt can be conveyed conveniently, and workers can move conveniently. The active carbon fiber dewatering system is provided with a first guide plate 23, a second guide plate 24 and a third guide plate 26, meanwhile, the inclination directions of the first guide plate 23 and the third guide plate 26 are opposite to the inclination direction of the second guide plate 24, the active carbon fiber dewatering system is provided with a transition box 39, and the interior of the transition box 39 is of a hollow structure and used for transition of carbon fiber felts.

In this embodiment, as shown in fig. 1 to fig. 6, the operation process of the dewatering system for activated carbon fiber provided in this embodiment is as follows:

step 1: the carbon fiber felt is guided by a guide shaft 18 and then sequentially enters the dehydration device 2 and the drying box 3;

step 2: the operation panel 46 starts the second motor 17 to drive the dehydration device 22 to primarily dehydrate the carbon fiber felt, then the carbon fiber felt enters the drying box 3, is rapidly frozen in the condensing box 27, is sublimated at high temperature in the sublimation box 28, and is finally cooled by the cooling box 29;

and step 3: and finally, directly conveying to the next procedure after being cooled by the rotating frame 6.

In conclusion, in this embodiment, according to the active carbon fiber dewatering system of this embodiment, the active carbon fiber dewatering system that this embodiment provided, this active carbon fiber dewatering system is equipped with dewatering device 2 and can goes out the inside most water extrusion of carbon fiber felt, be equipped with simultaneously that drying cabinet 3 can get into the sublimation case 28 inside sublimating after the carbon fiber felt gets into condenser box 27 quick freezing earlier, get into the cooling tank 29 cooling back at last and get into 6 internal rotation sunning of swivel mount, need not to carry out natural sunning, also need not to dry in the while with felt immigration drying equipment, and the time saving improves production efficiency. This active carbon fiber dewatering system is equipped with condensing box 27 and is equipped with condenser pipe 31 in the inside of condensing box 27 and can carry out quick freezing with guaranteeing the dry remaining moisture of microwave box 44, and it is inconvenient to guarantee the original inside microporous structure of carbon fiber felt, utilize simultaneously that sublimation box 28 is inside heating wire 32 to sublime the carbon fiber felt, make the direct sublimation of frozen hydrone become vapor and escape, the concentrated phenomenon can not take place because of the dehydration in the sublimation process, avoided producing the foam by vapor, side effects such as oxidation. The activated carbon fiber dehydration system is provided with a temperature sensor 30 capable of constantly detecting the temperature of the condensation tank 27 and the sublimation tank 28 and transmitting the temperature to the operation panel 46 for constantly controlling the temperature change. The active carbon fiber dewatering system is provided with a first guide plate 23, a second guide plate 24 and a third guide plate 26, meanwhile, the inclination directions of the first guide plate 23 and the third guide plate 26 are opposite to the inclination direction of the second guide plate 24, the active carbon fiber dewatering system is provided with a transition box 39, and the interior of the transition box 39 is of a hollow structure and used for transition of carbon fiber felts.

The above description is only for the purpose of illustrating the present invention and is not intended to limit the scope of the present invention, and any person skilled in the art can substitute or change the technical solution of the present invention and its conception within the scope of the present invention.

Claims (9)

1. The active carbon fiber dewatering system is characterized by comprising a base (1) and supporting plates (5) installed on two sides of the top of the base (1), wherein a positioning plate (4) is fixedly connected to the top of the supporting plate (5), supporting rods (19) are fixedly installed at one end of the positioning plate (4), a rotating frame (6) is fixedly installed between the supporting rods (19), a drying box (3) is fixedly installed between the supporting plates (5), a dewatering device (2) is arranged below the drying box (3), the dewatering device (2) comprises a first extrusion roller (13) and a second extrusion roller (14) installed below the first extrusion roller (13), a guide shaft (18) is arranged on one side of the second extrusion roller (14), the first extrusion roller (13), the second extrusion roller (14) and one end of the guide shaft (18) are provided with a driven gear (15), a support table (42) is arranged above the drying box (3), a second motor (17) is fixedly arranged at the top of the support table (42), the output end of the second motor (17) is connected with a driving gear (43), the driving gear (43) is connected with a plurality of driven gears (15) through a chain (16), the drying box (3) comprises a second drying device (38), a transition box (39) and a second drying device (40) which are sequentially arranged above the second drying device (38) from bottom to top, the second drying device (38) comprises a microwave box (44) and a first guide plate (23), a second guide plate (24) and a third guide plate (26) which are arranged in the microwave box (44) in a staggered distribution, magnetrons (25) are respectively arranged on two sides of the first guide plate (23), and a choke box (22) is arranged below the microwave box (44).

2. The activated carbon fiber dewatering system according to claim 1, wherein a wave-shaped flow resisting plate (21) is provided in the flow resisting tank (22), and one side of the flow resisting plate (21) is provided with the flow resisting plate (21) communicated with the microwave tank (44).

3. The active carbon fiber dehydration system of claim 1, wherein said second drying device (40) comprises a condensation box (27), a sublimation box (28) and a cooling box (29) sequentially installed above said condensation box (27) from bottom to top, said condensation box (27) having a condensation pipe (31) at both ends, said sublimation box (28) having a plurality of heating wires (32) inside, said second drying device (40) having an air outlet (41) on the outer wall for ventilation of said sublimation box (28), said cooling box (29) having a plurality of uniformly distributed circulation fans (33) inside.

4. Active carbon fiber dehydration system according to claim 3 characterized in that said condensation tank (27) and said sublimation tank (28) are provided inside with temperature sensors (30), and said condensation tank (27), sublimation tank (28) and cooling tank (29) are provided inside with outlets (34).

5. The activated carbon fiber dewatering system according to claim 1, wherein a nitrogen tank (35) is arranged below the drying tank (3), an air pump (36) is arranged inside the nitrogen tank (35), and an output end of the air pump (36) is communicated with the second drying device (38) through an air pipe (37).

6. The active carbon fiber dewatering system according to claim 1, wherein the rotating frame (6) comprises a support frame (7) and second support rollers (9) installed at two ends of the support frame (7), a first motor (12) is fixedly installed on the support rod (19), a first support roller (8) is fixedly connected to an output end of the first motor (12), and the other end of the first support roller (8) is movably installed on the support frame (7).

7. The activated carbon fiber dewatering system according to claim 1, wherein a driven gear (15) is installed below the supporting rod (19) in an inclined manner, one end of the inclined rod (45) is fixedly installed on the supporting rod (19), the other end of the inclined rod (45) is fixedly installed on the positioning plate (4), and a third supporting roller (10) and a fourth supporting roller (11) are fixedly installed between the two inclined rods (45).

8. The dewatering system for activated carbon fibers according to claim 1, wherein the first guide plate (23), the second guide plate (24) and the third guide plate (26) are all hollowed-out guide plates.

9. The activated carbon fiber dewatering system according to claim 1, wherein the base (1) is provided with an operation panel (46) that cooperates with the drying box (3).

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