CN218951105U - Novel iron-carbon reactor - Google Patents

Abstract

The utility model discloses a novel iron-carbon reactor, which comprises a reactor body, wherein a water inlet is formed in the water inlet end of the reactor body, the reactor body comprises a reaction zone and a sedimentation zone, a plurality of filler grids are vertically inserted in the reaction zone, iron-carbon fillers are filled in the filler grids, through holes are uniformly formed in the front side and the rear side of the filler grids, an overflow pipe is arranged on the upper side of the sedimentation zone, and a drain pipe is arranged on the lower side of the sedimentation zone; according to the utility model, through the disassembly and assembly of the filler grids and the forward moving process, the iron-carbon filler in each filler grid can be recycled, so that the utilization rate of the iron-carbon filler is effectively improved, and the treatment effect of the reactor is improved; in addition, the disassembly and assembly and the forward moving processes are simple and easy to operate, so that more operation time is not required for occupying manpower, and the disassembly and assembly processes are simplified; meanwhile, the vibration motor is started regularly, so that the reactor body and the filling grid can keep a vibration state, and the risk of hardening of the iron-carbon filling in the filling grid can be effectively reduced.

Description

Novel iron-carbon reactor

Technical Field

The utility model relates to the technical field of sewage advanced treatment and equipment manufacturing, in particular to a novel iron-carbon reactor.

Background

The iron-carbon filter material process is an ideal process for treating high-concentration organic wastewater, and is also called an internal electrolysis method. Under the condition of no power, the micro-electrolysis material filled in the waste water generates potential difference to carry out electrolysis treatment on the waste water so as to achieve the purpose of degrading organic pollutants. The technology is particularly aimed at treating wastewater which has high concentration of organic matters, high toxicity, high chromaticity and difficult biochemical treatment, can greatly reduce the chromaticity and COD of the wastewater, and improves the B/C ratio, namely the biodegradability of the wastewater; can be widely applied to the treatment of various industrial wastewater such as printing and dyeing, chemical industry, electroplating, pulping and papermaking, pharmacy, wool washing, pesticides, alcohol and the like and the recycling engineering of the treated water.

However, the iron-carbon filler in the iron-carbon reactor used at present exists in an acidic medium, is easy to harden into blocks after being soaked for a long time, and causes a blocking phenomenon, so that channeling is formed in the iron-carbon reactor, the treatment effect is reduced, the disassembly and assembly process is complex, the iron-carbon filler needs to be replaced again after being replaced for a long time, and more manual operation time is occupied.

Disclosure of Invention

The utility model aims to overcome the defects and provide a novel iron-carbon reactor so as to simplify the disassembly and assembly process and improve the treatment effect of the reactor.

The utility model aims to solve the technical problems, and adopts the technical scheme that: the utility model provides a novel iron-carbon reactor, includes the reactor body, the reactor body water inlet end is equipped with the water inlet, the reactor body includes reaction zone and sedimentation zone, vertical cartridge has a plurality of filler check in the reaction zone, it packs to have filled iron-carbon in the filler check, the through-hole has evenly been seted up to the side around the filler check, and the sedimentation zone upside is equipped with the overflow pipe, and the downside is equipped with the blow off pipe.

Preferably, a vibration motor is further arranged on one side of the reactor body.

Preferably, positioning columns are arranged on two sides of the filling grid and are in sliding fit with vertical grooves formed in the inner side wall of the reactor body.

Preferably, the inner side wall of the reactor body is also provided with a transverse groove, and the transverse groove is matched with the positioning column.

Preferably, the reactor body and the filler grid are both cuboid groove structures.

Preferably, the overflow pipe is provided with a first valve, and the sewage drain pipe is provided with a second valve.

The utility model has the beneficial effects that: according to the utility model, through the disassembly and assembly of the filler grids and the forward moving process, the iron-carbon filler in each filler grid can be recycled, so that the utilization rate of the iron-carbon filler is effectively improved, and the treatment effect of the reactor is improved; in addition, the disassembly and assembly and the forward moving processes are simple and easy to operate, so that more operation time is not required for occupying manpower, and the disassembly and assembly processes are simplified; meanwhile, the vibration motor is started regularly, so that the reactor body and the filling grid can keep a vibration state, and the risk of hardening of the iron-carbon filling in the filling grid can be effectively reduced.

Drawings

FIG. 1 is a schematic diagram of a novel iron-carbon reactor;

FIG. 2 is a schematic view of the packing lattice of FIG. 1;

fig. 3 is a schematic structural view of the reactor body 1.

Detailed Description

The utility model is described in further detail below with reference to the drawings and the specific examples.

As shown in fig. 1 to 3, a novel iron-carbon reactor comprises a reactor body 1, wherein a water inlet 2 is formed at the water inlet end of the reactor body 1, the reactor body 1 comprises a reaction zone 1.1 and a sedimentation zone 1.2, a plurality of filler grids 3 are vertically inserted in the reaction zone 1.1, iron-carbon fillers are filled in the filler grids 3, through holes 3.1 are uniformly formed in the front side and the rear side of the filler grids 3, an overflow pipe 4 is arranged on the upper side of the sedimentation zone 1.2, and a sewage drain pipe 5 is arranged on the lower side of the reactor.

Preferably, a vibration motor 6 is further provided at one side of the reactor body 1. By periodically starting the vibration motor 6, the reactor body 1 and the packing grid 3 can be kept in a vibration state, so that the risk of hardening of the iron-carbon packing in the packing grid 3 can be effectively reduced.

Preferably, positioning columns 7 are arranged on two sides of the packing lattice 3, and the positioning columns 7 are in sliding fit with vertical grooves 8 formed in the inner side wall of the reactor body 1. After the design, when the packing grid 3 is installed, the packing grid 3 is directly inserted into the reactor body 1 from top to bottom, and can be inserted into the vertical groove 8 through the positioning column 7 in an aligned manner, so that the packing grid 3 is limited in the reactor body 1 and cannot move back and forth; also, when the packing 3 needs to be pulled out, the packing 3 is directly pulled out from the bottom to the top, and the disassembly process can be completed.

Preferably, the inner side wall of the reactor body 1 is also provided with a transverse groove 9, and the transverse groove 9 is matched with the positioning column 7. As shown in fig. 1, the iron-carbon filler in the first filler cell 3 near the water inlet 2 consumes fastest, after the iron-carbon filler is pulled upwards and disassembled, the second filler cell 3 can be pulled upwards for a small distance, when the positioning column 7 reaches the transverse groove 9, the whole filler cell 3 is pushed forwards until the positioning column 7 enters the first vertical groove 8, the whole filler cell 3 is inserted downwards, the third filler cell 3 is pushed to the position of the second vertical groove 8 in sequence, and then the disassembled first filler cell 3 is inserted to the position of the third vertical groove 8 after the new iron-carbon filler is replaced again, so that the utilization rate of iron-carbon can be improved through forward movement of the plurality of filler cells 3.

Preferably, the reactor body 1 and the packing grid 3 are both rectangular groove structures.

Preferably, the overflow pipe 4 is provided with a first valve 4.1, and the sewage drain pipe 5 is provided with a second valve 5.1.

In this embodiment, after the wastewater after the reaction enters the precipitation zone 1.2, the wastewater can be further subjected to the strengthening treatment by adding a pH regulator or adding hydrogen peroxide, the precipitate generated in the treatment process is collected at the bottom, the upper layer is clear liquid, the clear liquid after the treatment can flow out of the overflow pipe 4 by opening the first valve 4.1, and after a period of treatment, the second valve 5.1 can be opened, the precipitated impurities in the precipitation zone 1.2 are discharged through the sewage drain pipe 5, the sewage drain pipe 5 can be externally connected with a slurry pump, and the discharging speed is accelerated.

The working principle of the embodiment is as follows:

the waste water to be treated enters the reactor body 1 from the water inlet 2 at the front end of the reactor body 1, then sequentially passes through the plurality of filler grids 3, iron carbon fillers in the filler grids 3 are in contact reaction with the waste water, impurities in the waste water can be effectively removed, after the waste water after reaction enters the sedimentation zone 1.2, the waste water can be further subjected to strengthening treatment by adding a pH regulator or adding hydrogen peroxide, sediment generated in the treatment process is gathered at the bottom, the upper layer is clear liquid, the clear liquid after treatment can flow out from the overflow pipe 4 by opening the first valve 4.1, and after a period of treatment, the second valve 5.1 can be opened, sediment impurities in the sedimentation zone 1.2 are discharged through the sewage pipe 5, the sewage pipe 5 can be externally connected with a mud pump, and the discharging speed is accelerated. In addition, the iron carbon filler in the first filler grid 3 near the water inlet 2 consumes fastest, the iron carbon filler in the rear filler grid 3 consumes less, so after a period of time to be treated, the first filler grid 3 can be pulled upwards to be disassembled, the iron carbon filler in the first filler grid 3 is replaced, then the second filler grid 3 is lifted upwards vertically for a small distance, when the positioning column 7 of the second filler grid reaches the position of the transverse groove 9, the whole filler grid 3 is moved forwards transversely until the positioning column 7 of the positioning column enters the first vertical groove 8, the first filler grid 3 is inserted downwards, the third filler grid 3 is pushed to the position of the second vertical groove 8 in sequence, then the disassembled first filler grid 3 with new iron carbon filler is inserted to the position of the third vertical groove 8, and therefore, only the iron carbon filler in one filler grid 3 needs to be replaced each time, and other filler grids 3 only need to be moved forwards to be in place, so that the effective iron carbon filler utilization rate of each filler grid 3 can be reused. Finally, the vibration motor 6 is started periodically, so that the reactor body 1 and the packing grid 3 can be kept in a vibration state, and the risk of hardening of the iron-carbon packing in the packing grid 3 can be effectively reduced.

The foregoing embodiments are merely preferred embodiments of the present utility model, and should not be construed as limiting the present utility model, and the embodiments and features of the embodiments in the present application may be arbitrarily combined with each other without collision. The protection scope of the present utility model is defined by the claims, and the protection scope includes equivalent alternatives to the technical features of the claims. I.e., equivalent replacement modifications within the scope of this utility model are also within the scope of the utility model.

Claims (6)

1. The utility model provides a novel iron carbon reactor, includes reactor body (1), reactor body (1) water inlet end is equipped with water inlet (2), its characterized in that: the reactor comprises a reactor body (1) and a sedimentation zone (1.1.2), wherein a plurality of filler grids (3) are vertically inserted in the reaction zone (1.1), iron-carbon fillers are filled in the filler grids (3), through holes (3.1) are uniformly formed in the front side and the rear side of the filler grids (3), an overflow pipe (4) is arranged on the upper side of the sedimentation zone (1.2), and a drain pipe (5) is arranged on the lower side of the sedimentation zone.

2. A novel iron carbon reactor as set forth in claim 1 wherein: one side of the reactor body (1) is also provided with a vibrating motor (6).

3. A novel iron carbon reactor as set forth in claim 1 wherein: positioning columns (7) are arranged on two sides of the packing lattice (3), and the positioning columns (7) are in sliding fit with vertical grooves (8) formed in the inner side wall of the reactor body (1).

4. A novel iron carbon reactor according to claim 3, wherein: the inner side wall of the reactor body (1) is also provided with a transverse groove (9), and the transverse groove (9) is matched with the positioning column (7).

5. A novel iron carbon reactor as set forth in claim 1 wherein: the reactor body (1) and the filler grid (3) are both of cuboid groove structures.

6. A novel iron carbon reactor as set forth in claim 1 wherein: the overflow pipe (4) is provided with a first valve (4.1), and the sewage draining pipe (5) is provided with a second valve (5.1).

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