CN211111239U - Iron carbon oxidation device - Google Patents

Abstract

The utility model discloses an iron carbon oxidation unit relates to the oxidation reactor field, for the current not high problem of oxidation treatment device oxidation reaction efficiency among the solution prior art. The below of alkali jar is provided with neutralization pond, the speed reducer is installed to the top in neutralization pond, second driving motor is installed to the upper end of speed reducer, the liquid outlet is installed to one side of neutralization pond below, the inside of acid tank is provided with the inlet tube, the internally mounted of reaction tank has the iron carbon mount, bubble generator is installed to the below of iron carbon mount, bubble generator's top is provided with the shower nozzle, the internally mounted in neutralization pond has the second circulating pump, the pivot is installed to one side of second circulating pump, the externally mounted of pivot has the stirring rake, the alkali mouth is installed into to the inside top in neutralization pond, the internally mounted of iron carbon mount has the iron carbon connecting rod, one side of iron carbon connecting rod is provided with the opening.

Description

Iron carbon oxidation device

Technical Field

The utility model relates to an oxidation reactor technical field specifically is an iron carbon oxidation unit.

Background

In recent years, pollution problems are more and more emphasized, government and various industry departments adopt stricter control standards and measures, although a pollution treatment method is applied to actual production, due to the limitation of the pollution treatment method, an effective technical method is still lacked for toxic and difficultly-degraded biochemical wastewater, such as sewage discharged by enterprises of pesticides, pharmacy, papermaking, dyes and the like, with the continuous progress of science and technology, a novel water pollution treatment technology begins to show unique effects, a catalytic oxidation technology is a typical representative of the technology, the catalytic oxidation technology mainly comprises ozone catalytic oxidation, photocatalytic oxidation, fenton catalytic oxidation and the like, and the main components of the wastewater are stannous sulfate, phenolsulfonic acid, phenol and organic additives.

The iron-carbon micro-electrolysis technology takes waste scrap iron and activated carbon particles as the filling materials of a reactor, utilizes the difference of oxidation reduction potentials of iron and carbon to enable the waste scrap iron and the activated carbon particles to form countless micro primary batteries in the reactor, reduces and degrades organic pollutants in wastewater, does not need additional current for iron-carbon internal electrolysis, has low cost and plays a role in preparing waste with waste, but the existing oxidation treatment device has low oxidation reaction efficiency and influences the work; therefore, the market is urgently needed to develop an iron carbon oxidation device to help people to solve the existing problems.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an iron carbon oxidation unit to solve the current not high problem of oxidation treatment device oxidation reaction efficiency that provides among the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: an iron-carbon oxidation device comprises an acid tank, wherein a reaction tank is arranged on one side of the acid tank, an inlet is installed at the upper end of the acid tank, a first circulating pump is installed above the reaction tank, a first driving motor is installed above the first circulating pump, connecting pipes are installed on two sides of the first circulating pump, a feed inlet is formed in one side of each connecting pipe, a cover is installed at the upper end of the feed inlet, an acidity display screen is installed on the front end face of the acid tank, an alkali tank is installed on one side of the reaction tank, an alkalinity display screen is arranged on the front end face of the alkali tank, a valve is installed below the alkalinity display screen, a neutralization tank is arranged below the alkali tank, a speed reducer is installed above the neutralization tank, a second driving motor is installed at the upper end of the speed reducer, a liquid outlet is installed on one side below the neutralization tank, and a water inlet pipe is arranged inside the acid tank, the internally mounted of reaction tank has the iron carbon mount, bubble generator is installed to the below of iron carbon mount, bubble generator's top is provided with the shower nozzle, the internally mounted of neutralization pond has the second circulating pump, the pivot is installed to one side of second circulating pump, the externally mounted of pivot has the stirring rake, the alkali mouth is installed into to the inside top in neutralization pond, the internally mounted of iron carbon mount has the iron carbon connecting rod, one side of iron carbon connecting rod is provided with the opening.

Preferably, the acid tank is connected with the reaction tank through a fixing screw, the first circulating pump is connected with the reaction tank through a fixing screw, the first driving motor is electrically connected with the first circulating pump, the first circulating pump is connected with the connecting pipe in a sealing manner, and the connecting pipe extends to the inside of the acid tank and the reaction tank and is connected with the acid tank and the reaction tank in a sealing manner respectively.

Preferably, the feed inlet is connected with the reaction tank in a sealing manner, the opening cover is connected with the feed inlet through a hinge, and a switch button is arranged on the front end face of the reaction tank.

Preferably, the alkali jar passes through fixed screw with the neutralization pond and is connected, neutralization pond and reaction tank welded connection, the inlet tube is installed to the below of alkali jar, and the inlet tube extends to the reaction tank inside with advance alkali mouth sealing connection.

Preferably, the second driving motor and the speed reducer are fixedly connected through a coupler, the rotating shaft and the speed reducer are fixedly connected through a coupler, the stirring paddle and the rotating shaft are fixedly connected, and the second circulating pump is respectively in sealing connection with the reaction tank and the neutralization tank.

Preferably, the iron-carbon fixing frame is fixedly connected with the reaction tank through a clamping groove, the iron-carbon connecting rod is fixedly connected with the iron-carbon fixing frame, and the bubble generator is connected with the reaction tank through a fixing screw.

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

the utility model pours the materials into the reaction tank through the feed inlet by arranging the iron-carbon fixing frame, leading acid materials from the acid tank to the inside of the reaction tank through the first circulating pump, reacting with the materials in the reaction tank, enabling the materials and the acid materials to pass through the iron-carbon fixing frame, the oxidation reaction between the materials and the iron-carbon connecting rods is carried out through the iron-carbon connecting rods and the through holes in the iron-carbon fixing frame, the using amount of the oxidant is reduced, the cost is saved, the iron and the carbon can be formed into countless tiny primary batteries in the reaction tank by utilizing the difference of the oxidation reduction potential of the iron and the carbon, the organic pollution in the materials is reduced and degraded, injecting air into the solution through the bubble generator and the nozzle, and generating bubbles to keep the interior of the reaction tank in an active state, the iron-carbon fixing frame is in continuous contact with the iron-carbon fixing frame, so that the solution oxidation efficiency is improved, and the working efficiency is improved.

Drawings

FIG. 1 is a front view of an iron carbon oxidation apparatus according to the present invention;

FIG. 2 is a view showing an internal structure of an iron carbon oxidation apparatus according to the present invention;

fig. 3 is a schematic view of the iron-carbon fixing frame of the present invention.

In the figure: 1. an acid tank; 2. a reaction tank; 3. a liquid inlet; 4. a first circulation pump; 5. a first drive motor; 6. a connecting pipe; 7. a feed inlet; 8. a flap; 9. an acidity display screen; 10. an alkali tank; 11. an alkalinity display screen; 12. a valve; 13. a second drive motor; 14. a speed reducer; 15. a neutralization pond; 16. a liquid outlet; 17. a water inlet pipe; 18. an iron-carbon fixing frame; 19. a bubble generator; 20. a spray head; 21. a second circulation pump; 22. a rotating shaft; 23. a stirring paddle; 24. an alkali inlet; 25. an iron-carbon connecting rod; 26. and (6) a port.

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.

Referring to fig. 1-3, the present invention provides an embodiment: an iron carbon oxidation device comprises an acid tank 1, a reaction tank 2 is arranged on one side of the acid tank 1, a liquid inlet 3 is installed at the upper end of the acid tank 1, a first circulating pump 4 is installed above the reaction tank 2, a first driving motor 5 is installed above the first circulating pump 4, connecting pipes 6 are installed on two sides of the first circulating pump 4, a feed inlet 7 is arranged on one side of each connecting pipe 6, a cover 8 is installed at the upper end of each feed inlet 7, an acidity display screen 9 is installed on the front end face of the acid tank 1, an alkali tank 10 is installed on one side of the reaction tank 2, an alkalinity display screen 11 is arranged on the front end face of the alkali tank 10, a valve 12 is installed below the alkalinity display screen 11, a neutralization tank 15 is arranged below the alkali tank 10, a speed reducer 14 is installed above the neutralization tank 15, a second driving motor 13 is installed on the upper end of the speed reducer 14, a liquid outlet 16 is installed on one side below the neutralization, reaction tank 2's internally mounted has iron carbon mount 18, bubble generator 19 is installed to the below of iron carbon mount 18, bubble generator 19's top is provided with shower nozzle 20, the internally mounted of neutralization pond 15 has second circulating pump 21, pivot 22 is installed to one side of second circulating pump 21, the externally mounted of pivot 22 has stirring rake 23, alkali inlet 24 is installed to the inside top of neutralization pond 15, the internally mounted of iron carbon mount 18 has iron carbon connecting rod 25, one side of iron carbon connecting rod 25 is provided with opening 26.

Further, acid tank 1 is connected with reaction tank 2 through the fixed screw, first circulating pump 4 passes through the fixed screw with reaction tank 2 and is connected, first driving motor 5 and 4 electric connection of first circulating pump, first circulating pump 4 and 6 sealing connection of connecting pipe, inside and to acid tank 1 and reaction tank 2 sealing connection that connecting pipe 6 extends to acid tank 1 and reaction tank 2 respectively, through first circulating pump 4 from 1 leading-in sour material of acid tank to reaction tank 2 inside.

Further, feed inlet 7 and reaction tank 2 sealing connection, flap 8 and feed inlet 7 pass through hinged joint, and the preceding terminal surface of reaction tank 2 is provided with the switch button, but through switch button start-up bubble generator 19, second driving motor 13, first circulating pump 4 and second circulating pump 21.

Further, alkali jar 10 passes through fixed screw with neutralization pond 15 and is connected, neutralization pond 15 and 2 welded connection of reaction tank, and the inlet tube is installed to the below of alkali jar 10, and the inlet tube extends to 2 inside and advance alkali mouth 24 sealing connection in reaction tank, through second circulating pump 21 with solution leading-in neutralization pond 15 inside, open valve 12 with alkali lye inflow neutralization pond 15 inside with solution carry out neutralization.

Further, second driving motor 13 passes through shaft coupling fixed connection with speed reducer 14, and pivot 22 passes through shaft coupling fixed connection with speed reducer 14, stirring rake 23 and pivot 22 fixed connection, second circulating pump 21 respectively with reaction tank 2 and neutralization pond 15 sealing connection, drive stirring rake 23 through second driving motor 13 and speed reducer 14 and stir to improve the reaction effect.

Further, iron carbon mount 18 passes through draw-in groove fixed connection with reaction tank 2, iron carbon connecting rod 25 and iron carbon mount 18 fixed connection, and bubble generator 19 passes through fixed screw connection with reaction tank 2, through bubble generator 19 and shower nozzle 20 with the inside air that injects of solution, and the production bubble for reaction tank 2 is inside always in the active state.

The working principle is as follows: when the device is used, materials are poured into the reaction tank 2 through the feed port 7, the acid materials are led into the reaction tank 2 from the acid tank 1 through the first circulating pump 4 and react with the materials in the reaction tank 2, the materials and the acid materials pass through the iron-carbon fixing frame 18, oxidation reaction is carried out between the materials and the iron-carbon connecting rod 25 through the iron-carbon connecting rod 25 and the through hole 26 in the iron-carbon fixing frame 18, the using amount of an oxidant is reduced, the cost is saved, the iron and the carbon can be oxidized and reduced into countless micro primary batteries in the reaction tank 2 by utilizing the difference of oxidation and reduction potentials of the iron and the carbon, organic pollution in the materials is reduced and degraded, air is injected into the solution through the bubble generator 19 and the spray head 20 to generate bubbles, so that the inside of the reaction tank 2 is always in an active state and is continuously contacted with the iron-carbon fixing frame 18, the bubble generator 19, the, Second driving motor 13, first circulating pump 4 and second circulating pump 21 open inside second circulating pump 21 with the leading-in neutralization pond 15 of solution, open valve 12 and flow into neutralization pond 15 inside with solution and carry out the neutralization, open second driving motor 13 and speed reducer 14 and drive stirring rake 23 and stir to improve the reaction effect, discharge the solution after will oxidizing through liquid outlet 16.

It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (6)

1. The utility model provides an iron carbon oxidation unit, includes acid tank (1), its characterized in that: one side of the acid tank (1) is provided with a reaction tank (2), a liquid inlet (3) is installed at the upper end of the acid tank (1), a first circulating pump (4) is installed above the reaction tank (2), a first driving motor (5) is installed above the first circulating pump (4), connecting pipes (6) are installed on two sides of the first circulating pump (4), a feeding hole (7) is formed in one side of each connecting pipe (6), a cover (8) is installed at the upper end of the feeding hole (7), an acidity display screen (9) is installed on the front end face of the acid tank (1), an alkali tank (10) is installed on one side of the reaction tank (2), an alkalinity display screen (11) is arranged on the front end face of the alkali tank (10), a valve (12) is installed below the alkalinity display screen (11), and a neutralization tank (15) is arranged below the alkali tank (10), speed reducer (14) is installed to the top of neutralization pond (15), second driving motor (13) is installed to the upper end of speed reducer (14), liquid outlet (16) is installed to one side of neutralization pond (15) below, the inside of acid tank (1) is provided with inlet tube (17), the internally mounted of reaction tank (2) has iron carbon mount (18), bubble generator (19) is installed to the below of iron carbon mount (18), the top of bubble generator (19) is provided with shower nozzle (20), the internally mounted of neutralization pond (15) has second circulating pump (21), pivot (22) is installed to one side of second circulating pump (21), the externally mounted of pivot (22) has stirring rake (23), alkali inlet (24) is installed to the inside top of neutralization pond (15), the internally mounted of iron carbon mount (18) has iron carbon connecting rod (25), one side of the iron-carbon connecting rod (25) is provided with a through hole (26).

2. An iron carbon oxidation plant according to claim 1, characterized in that: the acid tank (1) is connected with the reaction tank (2) through a fixing screw, the first circulating pump (4) is connected with the reaction tank (2) through a fixing screw, the first driving motor (5) is electrically connected with the first circulating pump (4), the first circulating pump (4) is connected with the connecting pipe (6) in a sealing manner, and the connecting pipe (6) extends to the interior of the acid tank (1) and the reaction tank (2) and is connected with the acid tank (1) and the reaction tank (2) in a sealing manner respectively.

3. An iron carbon oxidation plant according to claim 1, characterized in that: feed inlet (7) and reaction tank (2) sealing connection, flap (8) pass through hinged joint with feed inlet (7), the preceding terminal surface of reaction tank (2) is provided with the switch button.

4. An iron carbon oxidation plant according to claim 1, characterized in that: alkali jar (10) and neutralization pond (15) are through fixed screw connection, neutralization pond (15) and reaction tank (2) welded connection, the inlet tube is installed to the below of alkali jar (10), and the inlet tube extends to reaction tank (2) inside and advance alkali mouth (24) sealing connection.

5. An iron carbon oxidation plant according to claim 1, characterized in that: second driving motor (13) and speed reducer (14) pass through shaft coupling fixed connection, pivot (22) and speed reducer (14) pass through shaft coupling fixed connection, stirring rake (23) and pivot (22) fixed connection, second circulating pump (21) respectively with reaction tank (2) and neutralization pond (15) sealing connection.

6. An iron carbon oxidation plant according to claim 1, characterized in that: iron carbon mount (18) and reaction tank (2) pass through draw-in groove fixed connection, iron carbon connecting rod (25) and iron carbon mount (18) fixed connection, bubble generator (19) pass through fixed screw connection with reaction tank (2).

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