CN217709046U - A energy-efficient dynamic ionic membrane oxygenation equipment for river course sewage is administered - Google Patents

Abstract

The utility model discloses a high-efficient energy-conserving dynamic ionic membrane oxygenation equipment for river course sewage is administered relates to river course sewage and administers the field. This a high-efficient energy-conserving dynamic ionic membrane oxygen equipments for river course sewage is administered: the interior of the oxygenation box body is divided into a fan area, an electric control area and a pipeline area; the device comprises a first return pipe and a second return pipe, wherein the end parts of the first return pipe and the second return pipe are connected with a return pump in a river channel, and the other ends of the first return pipe and the second return pipe are provided with a component oxygenation mechanism. This a high-efficient energy-conserving dynamic ionic membrane oxygen equipments for river course sewage is administered observes the airflow in first airflow tube and the second airflow tube through two flowmeters, and then can control, and first airflow tube and second airflow tube deliver quantitative air current respectively to first oxygen increasing rifle and second oxygen increasing rifle in, and control that can be free increases oxygen volume, is convenient for control good oxygen pond and oxygen deficiency pond and forms.

Description

A energy-efficient dynamic ionic membrane oxygenation equipment for river course sewage is administered

Technical Field

The utility model relates to a river course sewage treatment technical field specifically is a high-efficient energy-conserving dynamic ionic membrane oxygenation equipment for river course sewage treatment.

Background

In the process of sewage treatment, a common mode is to arrange an aerobic tank, an anoxic tank and an anaerobic tank, wherein the aerobic tank is used for aerobic respiration of activated sludge to further decompose organic matters into inorganic matters. And (4) removing pollutants. The anaerobic tank utilizes the function of anaerobic bacteria to remove organic matters in the wastewater, and usually needs a long time. The anoxic tank mainly plays a role in removing nitrate nitrogen through denitrification and simultaneously removes partial BOD. It also has the function of improving biodegradability through hydrolysis reaction.

But the oxygenation efficiency of the traditional aeration device is low, the energy consumption is high, and the effect of improving the water quality is not obvious, because the big bubbles generated by the traditional aeration device rise fast in water, and the oxygenation degree of each area is not conveniently controlled, so that the formation of an aerobic pool and an anoxic pool is not conveniently controlled, and therefore, the high-efficiency energy-saving dynamic ionic membrane oxygenation equipment for treating the river sewage is provided.

SUMMERY OF THE UTILITY MODEL

Technical problem to be solved

The utility model discloses a not enough to prior art, the utility model discloses a high-efficient energy-conserving dynamic ionic membrane oxygen equipments for river course sewage is administered to solve the oxygenation inefficiency of the traditional aeration equipment that proposes in the above-mentioned background art, energy resource consumption is high, and is not obvious to improving quality of water effect, and the big bubble that the reason lies in traditional aeration equipment production is fast at aquatic rising speed, does not have the oxygenation degree in every region of convenient control simultaneously, is not convenient for control the problem of the formation in good oxygen pond and oxygen deficiency pond.

(II) technical scheme

In order to achieve the above purpose, the utility model discloses a following technical scheme realizes: the utility model provides an energy-efficient dynamic ionic membrane oxygen equipments for river course sewage is administered, includes oxygenation box, first back flow pipe and second back flow:

the oxygen increasing box body is internally welded with a plurality of partition plates, the internal space of the oxygen increasing box body is divided into a fan area, an electric control area and a pipeline area through the plurality of partition plates, and the pipeline area is positioned below the fan area and the electric control area;

the oxygen increasing box comprises a first return pipe and a second return pipe, wherein a first through pipe hole and a second through pipe hole which are communicated with a pipeline area are formed in the outer wall of one side of the oxygen increasing box body, the end portions of the first return pipe and the second return pipe are connected with a return pump in a river channel, the other ends of the first return pipe and the second return pipe respectively penetrate through the first through pipe hole and the second through pipe hole to extend inwards, and the first return pipe and the second return pipe are assembled with a component oxygen increasing mechanism.

Preferably, the component oxygen increasing mechanism mainly comprises an air blower, the air blower is arranged on the inner wall of the air blower area, the air blower is provided with two air outlets, and the two air outlets are respectively provided with a first airflow pipe and a second airflow pipe;

the end part of the first airflow pipe is provided with a first oxygen increasing gun, and the top end of the first reflux pipe is fixedly connected with the first oxygen increasing gun;

the end part of the second airflow pipe is provided with a second oxygen increasing gun, and the top end of the second return pipe is fixedly connected with the second oxygen increasing gun.

Preferably, a first water outlet pipe is mounted at the end part of the first oxygen increasing gun, a third pipe penetrating hole communicated with the pipeline area is formed in the outer wall of the oxygen increasing box body, and the end part of the first water outlet pipe penetrates through the third pipe penetrating hole and extends into the river channel;

and a second water outlet pipe is mounted at the end part of the second oxygen increasing gun, a fourth pipe penetrating hole communicated with the pipeline area is formed in the outer wall of the oxygen increasing box body, and the second water outlet pipe penetrates through the fourth pipe penetrating hole and extends into the river channel.

Preferably, the outer wall of the other side of the oxygen increasing box body is provided with two first through holes and two second through holes;

the end part of the first air flow pipe extends outwards through the first through hole at the lower part and extends towards the pipeline area through the first through hole at the upper part;

the end of the second gas flow tube extends outward through the second lower aperture and extends into the tube region through the second upper aperture.

Preferably, the flow meters are arranged on the external surfaces of the external parts of the first gas flow pipe and the second gas flow pipe.

The utility model discloses a high-efficient energy-conserving dynamic ionic membrane oxygenation equipment for river course sewage is administered, its beneficial effect who possesses as follows:

this a high-efficient energy-conserving dynamic ionic membrane oxygen equipments for river course sewage is administered, through the weight oxygenation mechanism that sets up, the air-blower blows the air current respectively to first air current pipe and second air current pipe in, first air current pipe and second air current pipe are in during the external part surface all is equipped with the flowmeter, thereby observe the air flow in first air current pipe and the second air current pipe through two flowmeters, and then can control, first air current pipe and second air current pipe deliver quantitative air current respectively to first oxygen increasing rifle and second oxygen increasing rifle in, first return pipe and second return pipe make its and inside air current mix in the first oxygen increasing rifle of raw water pump respectively into and the second oxygen increasing rifle simultaneously, enter into first outlet pipe and second outlet pipe respectively after mixing, then discharge to the good oxygen pond and the oxygen deficiency pond of river course, control oxygen increase amount that can be free, be convenient for control good oxygen pond and oxygen deficiency pond form.

This a high-efficient energy-conserving dynamic ionic membrane oxygen equipments for river course sewage is administered, through the first oxygen lance that increases that sets up and second increase the oxygen lance, the raw water just discharges through first outlet pipe and second outlet pipe after first oxygen lance and the second increase oxygen lance mix for the mixed effect of air water is better, and the bubble is long at aquatic dwell time, can improve the oxygen content of aquatic rapidly.

Drawings

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

FIG. 2 is a side sectional view of the present invention;

fig. 3 is a second side sectional view of the present invention;

FIG. 4 is a schematic side view of the present invention;

fig. 5 is a top cross-sectional view of the present invention.

In the figure: 1. an oxygenation box body; 101. a fan area; 102. an electric control area; 103. a pipeline area; 2. a first return pipe; 201. a first perforation hole; 202. a first water outlet pipe; 203. a third perforation hole; 3. a second return pipe; 301. a second perforation hole; 302. a second water outlet pipe; 303. a fourth perforation hole; 4. a blower; 401. a first gas flow pipe; 402. a second gas flow tube; 403. a first oxygen increasing lance; 404. a second oxygen increasing lance; 405. a first through hole; 406. a second through hole; 407. a flow meter.

Detailed Description

The embodiment of the utility model discloses energy-efficient dynamic ionic membrane oxygenation equipment for river course sewage is administered.

According to the attached drawings 1-5, the aerator comprises an aeration tank body 1, a first return pipe 2 and a second return pipe 3:

the oxygen increasing box comprises an oxygen increasing box body 1, wherein a plurality of partition plates are welded in the oxygen increasing box body 1, the internal space of the oxygen increasing box body 1 is divided into a fan area 101, an electric control area 102 and a pipeline area 103 through the plurality of partition plates, and the pipeline area 103 is positioned below the fan area 101 and the electric control area 102;

the oxygen increasing box comprises a first return pipe 2 and a second return pipe 3, wherein a first through hole 201 and a second through hole 301 communicated with a pipeline area 103 are formed in the outer wall of one side of the oxygen increasing box body 1, the end parts of the first return pipe 2 and the second return pipe 3 are connected with a return pump in a river channel, the other ends of the first return pipe 2 and the second return pipe 3 respectively penetrate through the first through hole 201 and the second through hole 301 to extend inwards, and the first return pipe 2 and the second return pipe 3 are assembled with a component oxygen increasing mechanism;

through the component oxygenation mechanism that sets up, air blower 4 blows the air current respectively to first air current pipe 401 and second air current pipe 402 in, the partial surface that first air current pipe 401 and second air current pipe 402 are in the external world all is equipped with flowmeter 407, thereby observe the air current in first air current pipe 401 and second air current pipe 402 through two flowmeters 407, and then can control, first air current pipe 401 and second air current pipe 402 deliver quantitative air current respectively to first oxygen increasing rifle 403 and second oxygen increasing rifle 404 in, first return pipe 2 and second return pipe 3 pump raw water respectively into first oxygen increasing rifle 403 and second oxygen increasing rifle 404 in make it mix with inside air current simultaneously, enter into first outlet pipe 202 and second outlet pipe 302 respectively after mixing, then discharge to the good oxygen pond and the oxygen deficiency pond of river regulation, increase oxygen quantity can free control, be convenient for control good oxygen pond and oxygen deficiency pond form.

The component oxygen increasing mechanism mainly comprises an air blower 4, wherein the air blower 4 is arranged on the inner wall of the fan area 101, the air blower 4 is provided with two air outlets, and the two air outlets are respectively provided with a first airflow pipe 401 and a second airflow pipe 402;

the end part of the first gas flow pipe 401 is provided with a first oxygen increasing lance 403, and the top end of the first return pipe 2 is fixedly connected with the first oxygen increasing lance 403;

the end part of the second airflow pipe 402 is provided with a second oxygen increasing gun 404, and the top end of the second return pipe 3 is fixedly connected with the second oxygen increasing gun 404;

through the arrangement of the first oxygen increasing lance 403 and the second oxygen increasing lance 404, raw water is mixed in the first oxygen increasing lance 403 and the second oxygen increasing lance 404 and then discharged through the first water outlet pipe 202 and the second water outlet pipe 302, so that the gas-water mixing effect is better, the retention time of bubbles in water is long, and the oxygen content in water can be rapidly improved.

A first water outlet pipe 202 is arranged at the end part of the first oxygen increasing gun 403, a third through hole 203 communicated with the pipeline area 103 is formed in the outer wall of the oxygen increasing box body 1, and the end part of the first water outlet pipe 202 extends into the river channel through the third through hole 203;

the end of the second oxygen increasing gun 404 is provided with a second water outlet pipe 302, the outer wall of the oxygen increasing box body 1 is provided with a fourth through hole 303 communicated with the pipeline area 103, and the second water outlet pipe 302 extends into the river channel through the fourth through hole 303.

Two first through holes 405 and two second through holes 406 are formed in the outer wall of the other side of the oxygenation box body 1;

the end of the first airflow pipe 401 extends outward through the first through hole 405 at the lower side, and extends into the pipe area 103 through the first through hole 405 at the upper side;

the end of the second airflow duct 402 extends outward through the second through hole 406 located below and extends into the duct area 103 through the second through hole 406 located above.

The exterior surfaces of the first and second gas flow tubes 401 and 402, which are external, are each equipped with a flow meter 407.

The working principle is as follows: in the use process, the blower 4 blows gas flows into the first gas flow pipe 401 and the second gas flow pipe 402 respectively, the outer surfaces of the external parts of the first gas flow pipe 401 and the second gas flow pipe 402 are provided with flow meters 407, so that the gas flows in the first gas flow pipe 401 and the second gas flow pipe 402 can be observed through the two flow meters 407, and then the control can be carried out, and the first gas flow pipe 401 and the second gas flow pipe 402 deliver quantitative gas flows into the first oxygen increasing lance 403 and the second oxygen increasing lance 404 respectively;

meanwhile, the first return pipe 2 and the second return pipe 3 pump raw water into the first oxygen increasing gun 403 and the second oxygen increasing gun 404 respectively to be mixed with the internal airflow, the raw water enters the first water outlet pipe 202 and the second water outlet pipe 302 respectively after the mixing is finished, and then the raw water is discharged into an aerobic pool and an anoxic pool for river treatment, so that the oxygen increasing amount can be freely controlled, and the formation of the aerobic pool and the anoxic pool is convenient to control;

and raw water is mixed in the first oxygen increasing lance 403 and the second oxygen increasing lance 404 and then is discharged through the first water outlet pipe 202 and the second water outlet pipe 302, so that the gas-water mixing effect is better, the retention time of bubbles in water is long, and the oxygen content in water can be rapidly improved.

The foregoing shows and describes the basic principles and principal features of the invention, together with the advantages thereof. It should be understood by those skilled in the art that the present invention is not limited to the above embodiments, and the above embodiments and descriptions are only illustrative of the principles of the present invention, and that various changes and modifications may be made without departing from the spirit and scope of the present invention, and all such changes and modifications fall within the scope of the present invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (5)

1. The utility model provides an energy-efficient dynamic ionic membrane oxygen equipments for river course sewage is administered, includes oxygenation box (1), first back flow pipe (2) and second back flow pipe (3), its characterized in that:

the oxygen increasing box comprises an oxygen increasing box body (1), wherein a plurality of partition plates are welded in the oxygen increasing box body (1), the internal space of the oxygen increasing box body (1) is divided into a fan area (101), an electric control area (102) and a pipeline area (103) through the plurality of partition plates, and the pipeline area (103) is positioned below the fan area (101) and the electric control area (102);

first back flow pipe (2) and second back flow pipe (3), set up first through hole (201) and second through hole (301) that are linked together with pipeline district (103) on the outer wall of one side of oxygenation box (1), the tip of first back flow pipe (2) and second back flow pipe (3) all is connected with the backwash pump in the river course, just the other end of first back flow pipe (2) and second back flow pipe (3) passes first through hole (201) and second through hole (301) respectively and inwards extends, just first back flow pipe (2) and second back flow pipe (3) are equipped with weight oxygenation mechanism.

2. The high-efficiency energy-saving dynamic ionic membrane oxygen increasing equipment for river course sewage treatment according to claim 1, which is characterized in that: the component oxygenation mechanism mainly comprises an air blower (4), the air blower (4) is installed on the inner wall of a blower area (101), the air blower (4) is provided with two air outlets, and a first airflow pipe (401) and a second airflow pipe (402) are respectively installed at the two air outlets;

the end part of the first gas flow pipe (401) is provided with a first oxygen increasing lance (403), and the top end of the first return pipe (2) is fixedly connected with the first oxygen increasing lance (403);

the end part of the second airflow pipe (402) is provided with a second oxygen increasing gun (404), and the top end of the second return pipe (3) is fixedly connected with the second oxygen increasing gun (404).

3. The high-efficiency energy-saving dynamic ionic membrane oxygen increasing equipment for river course sewage treatment according to claim 2, which is characterized in that: a first water outlet pipe (202) is mounted at the end part of the first oxygen increasing gun (403), a third through hole (203) communicated with the pipeline area (103) is formed in the outer wall of the oxygen increasing box body (1), and the end part of the first water outlet pipe (202) extends into the river channel through the third through hole (203);

the end part of the second oxygen increasing gun (404) is provided with a second water outlet pipe (302), the outer wall of the oxygen increasing box body (1) is provided with a fourth through hole (303) communicated with the pipeline area (103), and the second water outlet pipe (302) penetrates through the fourth through hole (303) and extends into the river channel.

4. The high-efficiency energy-saving dynamic ionic membrane oxygen increasing equipment for river course sewage treatment according to claim 2, which is characterized in that: two first through holes (405) and two second through holes (406) are formed in the outer wall of the other side of the oxygen increasing box body (1);

the end of the first air flow pipe (401) extends outwards through the first through hole (405) at the lower part and extends towards the pipeline area (103) through the first through hole (405) at the upper part;

the end of the second gas flow duct (402) extends through the second lower through-opening (406) and through the second upper through-opening (406) into the duct region (103).

5. The high-efficiency energy-saving dynamic ionic membrane oxygen increasing equipment for river sewage treatment according to claim 2, which is characterized in that: the outer surfaces of the parts, which are positioned outside, of the first airflow pipe (401) and the second airflow pipe (402) are both provided with a flowmeter (407).

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