CN211562980U - Active carbon regenerating unit - Google Patents

Abstract

The utility model discloses an active carbon regenerating unit, which comprises a housin, a plurality of support columns of casing bottom side fixedly connected with, it is connected with the apron to rotate on the lateral wall at the bottom of the casing, fixedly connected with is the magnesium iron heat accumulation board that the symmetry set up on the lateral wall at the bottom of the casing. The utility model discloses a cartridge heater, first swash plate, the second swash plate, magnesium iron heat accumulation board, the mating reaction of dwang, after activated carbon heating is accomplished in the heating chamber, make the activated carbon of high temperature fall in placing the chamber, pass through the feed inlet with new saturated charcoal again and get into between first swash plate and the second swash plate, the heat of activated carbon of high temperature gives new saturated charcoal with heat transfer, make new saturated charcoal preheat to higher temperature, saturated charcoal after preheating can improve the demand temperature more fast, repeat the operation again, the device reasonable in design, think about ingeniously, utilize the heat energy of the activated carbon after regeneration, the efficiency of production is improved, the production income of activated carbon has been increased.

Description

Active carbon regenerating unit

Technical Field

The utility model relates to an active carbon technical field especially relates to an active carbon regenerating unit.

Background

Activated carbon has a highly developed pore structure inside, and is often widely used as an adsorbent in industry, agriculture, national defense, and people's lives. However, activated carbon has a problem that its adsorption capacity is reduced or even completely lost after it is used for a certain period of time, and this activated carbon is called saturated carbon.

The activated carbon regeneration method includes a thermal regeneration method, an inorganic chemical regeneration method, an organic solvent regeneration method, a wet air oxidation method and the like, and the thermal regeneration method is to dry saturated carbon and then heat the dried saturated carbon in a regeneration furnace at about 850 ℃.

However, the saturated carbon is heated by using a heating regeneration method, the activated carbon can reach the required temperature only in a long time, and the regenerated activated carbon has extremely high temperature and is generally directly placed in an external environment to wait for being cooled and then packaged, so that a large amount of heat energy is wasted, and the production yield of the activated carbon is reduced.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing an active carbon regenerating unit, the use heating regeneration method who exists among the solution prior art heats saturated carbon, and the active carbon needs longer be the temperature that the time just can reach needs, and the active carbon after the regeneration has high temperature, generally just directly puts and waits to pack after the cooling in the external environment, has wasted a large amount of heat energy, has reduced the problem of the production income of active carbon.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

an active carbon regeneration device comprises a shell, wherein a plurality of support columns are fixedly connected to the bottom side of the shell, a cover plate is rotatably connected to the bottom side wall of the shell, symmetrically arranged magnesium-iron heat storage plates are fixedly connected to the inner bottom side wall of the shell, a heating cylinder is fixedly connected to the upper side of the magnesium-iron heat storage plates, a placing cavity is arranged below the heating cylinder, a heating cavity is arranged in the heating cylinder, the upper side wall and the lower side wall of the heating cylinder are in inverted cone-shaped downward inclination arrangement, a first through hole in penetrating arrangement is formed in the bottom end of the upper side wall of the heating cylinder, a second through hole in penetrating arrangement is formed in the bottom end of the lower side wall of the heating cylinder, a rotating rod in L-shaped arrangement is connected to the upper side wall of the shell in a penetrating manner, two baffles are fixedly connected to the rotating rod and are positioned, the utility model discloses a magnesium iron heat storage plate, including the dwang, the first rotation board of fixedly connected with and second rotation board on the dwang, the round hole has all been seted up on first rotation board and the second rotation board, first rotation board supports the below at first through-hole, the second rotation board supports the below at the second through-hole, be equipped with the heater in the heating cylinder, the both sides of casing are equipped with the feed inlet, two inside walls of casing are connected with the second swash plate through slider, every second swash plate downside fixedly connected with connecting rod, every the first swash plate of lower extreme fixedly connected with of connecting rod, first swash plate and second swash plate sliding connection are between casing inboard wall side and magnesium iron heat storage plate.

Preferably, the sliding device comprises an electric linear guide rail which is vertically arranged, each electric linear guide rail is fixedly connected to the inner side wall of the shell, a sliding block is connected to the inner side wall of the shell in a sliding mode, each sliding block is fixedly connected to the bottom side of the corresponding sliding block through a pull rod, and each second inclined plate is fixedly connected to the lower end of the corresponding pull rod.

Preferably, a moving groove is formed in the bottom side of each supporting column, a buffer spring is fixedly connected in each moving groove, and a universal wheel is fixedly connected at the bottom end of each buffer spring.

Preferably, the upper end fixedly connected with of dwang is the handle of oval setting, every be equipped with anti-skidding line on the handle.

Preferably, the shell is provided with an anti-oxidation coating which is uniformly sprayed on the surface of the shell.

Compared with the prior art, the beneficial effects of the utility model are that:

1. through the cartridge heater, first swash plate, the second swash plate, magnesium iron heat accumulation board, the mating reaction of dwang, after activated carbon heating is accomplished in heating the chamber, make high temperature activated carbon fall and place in the chamber, get into between first swash plate and the second swash plate with new saturated charcoal again through the feed inlet, the heat of high temperature activated carbon gives new saturated charcoal with heat transfer, make new saturated charcoal preheat to higher temperature, saturated charcoal after preheating can improve the demand temperature more fast, repeat the operation again, the device reasonable in design, think about ingeniously, utilize the heat energy of regenerated activated carbon, the efficiency of production is improved, the production income of activated carbon has been increased.

Drawings

Fig. 1 is a schematic front structural view of an activated carbon regeneration device provided by the present invention;

fig. 2 is a schematic top view of a first rotating plate of the activated carbon regeneration apparatus according to the present invention;

fig. 3 is a schematic top view of a second rotating plate in the activated carbon regeneration apparatus according to the present invention.

In the figure: the device comprises a support column 1, a first inclined plate 2, a connecting rod 3, a feed inlet 4, a second inclined plate 5, a pull rod 6, a heating cylinder 7, an electric linear guide rail 8, a shell 9, a baffle 10, a rotating rod 11, a first through hole 12, a first rotating plate 13, a sliding block 14, a magnesium-iron heat storage plate 15, a placing cavity 16, a cover plate 17, a second through hole 18, a second rotating plate 19, a heating cavity 20, a round hole 21 and a heater 22.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

In the description of the present invention, it should be understood that the indicated orientation or positional relationship is based on the orientation or positional relationship shown in the drawings, and is only for convenience of description and simplification of description, and does not indicate or imply that the indicated device or element must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the present invention.

Referring to fig. 1-3, an activated carbon regeneration device comprises a casing 9, a plurality of support columns 1 are fixedly connected to the bottom side of the casing 9, a cover plate 17 is rotatably connected to the bottom side wall of the casing 9, magnesium-iron heat storage plates 15 are fixedly connected to the bottom side wall of the casing 9, the magnesium-iron heat storage plates 15 are symmetrically arranged, a heating cylinder 7 is fixedly connected to the upper sides of the two magnesium-iron heat storage plates 15, a placing cavity 16 is arranged below the heating cylinder 7, a heating cavity 20 is arranged in the heating cylinder 7, the upper side wall and the lower side wall of the heating cylinder 7 are arranged in an inverted cone shape in a downward inclined manner, a first through hole 12 is arranged at the bottom end of the upper side wall of the heating cylinder 7 in a penetrating manner, a second through hole 18 is arranged at the bottom end of the lower side wall of the heating cylinder 7, a rotating rod 11 is arranged in an L shape and is fixedly connected to the upper side wall, the rotating rod 11 is fixedly connected with a first rotating plate 13 and a second rotating plate 19, round holes 21 are formed in the first rotating plate 13 and the second rotating plate 19, the round holes 21 in the first rotating plate 13 and the second rotating plate 19 are not located in the same vertical space, and when a handle at the upper end of the rotating rod 11 rotates to the right side to be horizontal, the first through hole 12 and the second through hole 18 are blocked by the first rotating plate 13 and the second rotating plate 19; when the upper end grip of the rotating rod 11 rotates to the front side level, the round hole 21 on the first rotating plate 13 is aligned with the first through hole 12, and the second through hole 18 is blocked by the second rotating plate 19; when the handle at the upper end of the rotating rod 11 rotates to the rear side level, the round hole 21 on the second rotating plate 19 aligns with the second through hole 18, the first rotating plate 13 blocks the first through hole 12, the first rotating plate 13 abuts against the lower side of the first through hole 12, the second rotating plate 19 abuts against the lower side of the second through hole 18, the heater 22 is arranged in the heating cylinder 7, the feed inlet 4 is arranged at two sides of the shell 9, the second inclined plate 5 is connected to two inner side walls of the shell 9 through a sliding device, the sliding device comprises vertically arranged electric linear guide rails 8 (wherein the electric linear guide rails 8 belong to the prior art, the working principle of the electric linear guide rails 8 is not described in detail herein), each electric linear guide rail 8 is fixedly connected to the inner side wall of the shell 9, a sliding block 14 is slidably connected to each electric linear guide rail 8, a pull rod 6 is fixedly connected to the bottom side of each sliding block 14, start electronic linear guide 8, can drive sliding block 14 and reciprocate, sliding block 14 can drive second swash plate 5 and first swash plate 2 through pull rod 6 and reciprocate, and then drive the material between second swash plate 5 and the first swash plate 2 and remove, 5 downside fixedly connected with connecting rod 3 of every second swash plate, the first swash plate 2 of lower extreme fixedly connected with of every connecting rod 3, first swash plate 2 and 5 sliding connection of second swash plate are between shell 9 inboard wall side and magnesium iron heat accumulation board 15.

The bottom side of each supporting column 1 is provided with a moving groove, a buffer spring is fixedly connected in each moving groove, the bottom end of each buffer spring is fixedly connected with a universal wheel, the buffer spring can buffer the impact force of the ground to the device, the universal wheels are symmetrically arranged, so that the device is more stable, and the device can be moved quickly and stably, the upper end of the rotating rod 11 is fixedly connected with oval grips, each grip is provided with anti-skid lines, the oval arrangement is more in line with the ergonomic design, the anti-skid coating is a galvanized coating, the oxidation speed of the galvanized coating can be slowed down twenty times compared with that of a non-galvanized material, the oxidation corrosion of air to the device can be greatly reduced, and the service life of the device is prolonged.

In the utility model, after the activated carbon is heated in the heating chamber 20, the upper end handle of the rotating rod 11 is rotated to the rear horizontal position, so that the high-temperature activated carbon falls in the placing chamber 16, and then the new saturated carbon enters between the first inclined plate 2 and the second inclined plate 5 through the feed inlet 4, the heat of the high-temperature activated carbon is mostly absorbed by the magnesium-iron heat storage plate 15, the magnesium-iron heat storage plate 15 transfers the heat to the new saturated carbon through heat, so that the new saturated carbon is preheated to a higher temperature, then the electric linear guide rail 8 is started to drive the first inclined plate 2 and the second inclined plate 5 to ascend, so that the new saturated carbon ascends, the saturated carbon slides to the upper side wall of the heating cylinder 7 through the first inclined plate 2, the upper end handle of the rotating rod 11 rotates to the front horizontal level, so that the preheated saturated carbon falls into the heating chamber 20, the heater 22 is opened again for heating, the preheated saturated carbon can be heated to a required temperature more quickly, later open apron 17 and take out the product of criticizing, repeat the operation again, the device reasonable in design, the design is ingenious, utilizes the heat energy of the active carbon after the regeneration, has improved the efficiency of production, has increased the production income of active carbon.

Claims (5)

1. The active carbon regeneration device comprises a shell (9) and is characterized in that a plurality of support columns (1) are fixedly connected to the bottom side of the shell (9), a cover plate (17) is rotatably connected to the bottom side wall of the shell (9), symmetrically arranged magnesium-iron heat storage plates (15) are fixedly connected to the bottom side wall of the shell (9), two heating cylinders (7) are fixedly connected to the upper sides of the magnesium-iron heat storage plates (15), a placing cavity (16) is arranged below the heating cylinders (7), a heating cavity (20) is arranged in the heating cylinders (7), the upper side wall and the lower side wall of each heating cylinder (7) are arranged in an inverted cone shape in a downward inclined mode, first through holes (12) which are arranged in a penetrating mode are formed in the bottom end of the upper side wall of each heating cylinder (7), second through holes (18) which are arranged in a penetrating mode are formed in the bottom end of the lower side wall of each heating cylinder (7), and an upper side wall of, two baffles (10) of fixedly connected with are arranged on the rotating rod, two baffles (10) are arranged on two sides of the upper side wall of the shell (9), the rotating rod (11) penetrates through the upper side wall and the lower side wall of the heating cylinder (7), the rotating rod (11) is fixedly connected with a first rotating plate (13) and a second rotating plate (19), round holes (21) are formed in the first rotating plate (13) and the second rotating plate (19), the first rotating plate (13) is supported below the first through hole (12), the second rotating plate (19) is supported below the second through hole (18), heaters (22) are arranged in the heating cylinder (7), feed inlets (4) are formed in two sides of the shell (9), two inner side walls of the shell (9) are connected with a second inclined plate (5) through a sliding device, and each second inclined plate (5) is fixedly connected with a connecting rod (3) on the lower side, the lower end of each connecting rod (3) is fixedly connected with a first inclined plate (2), and the first inclined plates (2) and the second inclined plates (5) are connected between the inner side wall side of the shell (9) and the magnesium-iron heat storage plate (15) in a sliding mode.

2. The activated carbon regeneration device according to claim 1, wherein the sliding device comprises vertically arranged electric linear guide rails (8), each electric linear guide rail (8) is fixedly connected to the inner side wall of the housing (9), a sliding block (14) is slidably connected in each electric linear guide rail (8), a pull rod (6) is fixedly connected to the bottom side of each sliding block (14), and each second inclined plate (5) is fixedly connected to the lower end of the pull rod (6).

3. The activated carbon regeneration device according to claim 1, wherein a moving groove is formed in the bottom side of each supporting column (1), a buffer spring is fixedly connected in each moving groove, and a universal wheel is fixedly connected to the bottom end of each buffer spring.

4. The activated carbon regeneration device according to claim 1, wherein an oval handle is fixedly connected to the upper end of the rotating rod (11), and each handle is provided with anti-skid lines.

5. The activated carbon regeneration device according to claim 1, wherein the housing (9) is provided with an anti-oxidation coating, and the anti-oxidation coating is uniformly sprayed on the surface of the housing (9).

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