CN220223661U - A device for treating sewage with iron-carbon micro-electrolysis composite biofilm - Google Patents

Abstract

The utility model relates to the technical field of sewage treatment, and specifically relates to a device for treating sewage with an iron-carbon micro-electrolysis composite biofilm, which includes a tank, which is the main working part of the sewage device with a pulverizing device installed on the top box; motor one, which is installed on one side of the surface of the crushing box; a rotating shaft, which is arranged inside the crushing box and connected to the output end of the motor one; a crushing roller, which is connected to one end of the rotating shaft, and two sets of crushing rollers Connected to the belt through a pulley. The utility model overcomes the shortcomings of the prior art. By arranging a motor, a crushing box and a crushing roller, sewage enters the crushing box through the water inlet. The operation of the motor drives the rotating shaft of the output end to rotate, so that the two wheels connected by the pulley and the belt The sets of crushing rollers rotate at the same time to crush impurities such as lumps in the sewage, so as to facilitate the normal circulation of sewage and reduce the blockage of the connecting pipes.

Description

A device for treating sewage with iron-carbon micro-electrolysis composite biofilm

Technical field

The utility model relates to the technical field of sewage treatment, specifically a device for treating sewage by an iron-carbon micro-electrolysis composite biofilm.

Background technique

Iron-carbon micro-electrolysis is a good process for treating wastewater using the principle of metal corrosion to form a primary battery. It is also called internal electrolysis method, iron filings filtration method, etc. It uses microorganisms filled in wastewater without electricity. The electrolytic material itself generates a 1.2V potential difference to electrolyze wastewater to achieve the purpose of degrading organic pollutants. Biofilm, also known as biofilm, refers to a substance attached to the surface of living or inanimate objects and wrapped by bacterial extracellular macromolecules. Organized bacterial groups and membrane organisms developed in recent years are used to improve the degree of sewage purification. Therefore, we propose a device for treating sewage with an iron-carbon micro-electrolysis composite biofilm.

According to the existing patent publication number: CN212076515U: a sewage treatment device based on the iron-carbon micro-electrolysis principle, including a treatment barrel, a water pipe is fixed in the middle of the top of the treatment barrel, and a water inlet is fixed in the middle of the top of the water pipe. , the interior of the treatment barrel is fixedly provided with a partition plate, the number of the partition plates is two, an iron-carbon filler layer is movable between the two partition plates, and the bottom end of the water pipe runs through And extends to the bottom of the partition plate at the bottom of the treatment barrel; this patent introduces sewage into the water pipe through the water inlet, but there are lumps and other impurities in the sewage. If it directly enters the inside, it will block the water pipe and reduce work efficiency; and will The air inlet pipe is connected to the oxygen, allowing oxygen to pass into the inside of the treatment barrel through the aerator on the surface of the air inlet pipe. However, there are particles and catkin-like impurities in the sewage. Under long-term working conditions, the impurities tend to adhere to the surface of the aerator, causing the aeration holes to be blocked, affecting the Aerator is functioning properly.

Utility model content

In view of the shortcomings of the existing technology, the utility model provides a device for treating sewage with an iron-carbon micro-electrolysis composite biofilm, aiming to solve the problem in the existing technology that lumpy impurities in the sewage are easy to block the water pipes, and the impurities are easy to clog the water pipes under long-term working conditions. The problem of clogging of aeration holes due to adhesion to the surface of the aerator.

In order to solve the above technical problems, the present utility model provides the following technical solutions:

A device for treating sewage with iron-carbon micro-electrolysis composite biofilm, including: a tank, which is the main working part of the device for treating sewage with iron-carbon micro-electrolysis composite biofilm, with a crushing box installed on the top; and a water inlet, which is installed at the The top center of the crushing box; motor one, which is installed on one side of the surface of the crushing box; a rotating shaft, which is arranged inside the crushing box and connected to the output end of the motor one; a crushing roller, which is connected to the One end of the rotating shaft, and the two sets of crushing rollers are connected to the belt through pulleys; a connecting horizontal plate, which is installed below the inside of the tank; a second motor, which is installed at the center of the bottom of the connecting horizontal plate; The rotating shaft is connected to the output end of the second motor, and a connecting plate is installed on one end of the rotating shaft; the cleaning brush is equidistantly arranged on one end of the connecting plate.

Preferably, the tank further includes: legs installed at the bottom four corners of the tank; a control panel installed on the surface of the tank, and the control panel is electrically connected to motor one and motor two respectively.

Preferably, the tank further includes: an aeration tube installed below the surface of the tank and extending to the inside of the tank; an aerator installed equidistantly on the top of the aeration tube and connected with the tank. The cleaning brushes are in contact.

Preferably, the tank further includes: a partition plate installed inside the tank, and two sets of partition plates divide the interior into iron-carbon filler layers; a filling port installed on the inside of the tank. surface and connected with the iron-carbon filler layer.

Preferably, the tank further includes: a water collection cap, which is installed inside the tank and connected to the upper partition; a water distribution cap, which is installed inside the tank and separated from the lower part. boards are connected.

Preferably, the tank further includes: an air outlet, which is provided above the surface of the tank and communicates with the tank; a communication pipe, which is connected inside the tank and communicates with the crushing box; A water outlet is provided above the surface of the tank, and a control valve is installed on the surface of the water outlet.

The embodiment of the present utility model provides a device for treating sewage with an iron-carbon micro-electrolysis composite biofilm, which has the following beneficial effects:

1. By setting up the motor one, the crushing box and the crushing roller, the sewage enters the crushing box through the water inlet. The operation of the motor one drives the rotating shaft at the output end to rotate, so that the two sets of crushing rollers connected by the pulley and the belt rotate at the same time, thereby crushing the crushing roller. Impurities such as lumps in the sewage are crushed to facilitate the normal circulation of the sewage, thereby reducing the clogging of the connecting pipes and facilitating the normal operation of the device.

2. By setting up the motor 2, the connecting plate and the cleaning brush, start the motor 2. The operation of the motor 2 drives the rotating shaft at the output end to rotate, and the connecting plate connected to one end rotates accordingly. Since the cleaning brush is in contact with the surface of the aerator, the cleaning During the rotation process, the brush clears the clogged aeration holes on the surface of the aerator to facilitate the normal operation of the aerator, thereby reducing the occurrence of clogging of the aeration holes.

Description of the drawings

The accompanying drawings are used to provide a further understanding of the present utility model, and constitute a part of the specification. They are used to explain the present utility model together with the embodiments of the present utility model, and do not constitute a limitation of the present utility model. In the attached picture:

Figure 1 is a schematic diagram of the overall structure of the utility model;

Figure 2 is a schematic diagram of the internal structure of the crushing box of the present utility model;

Figure 3 is a schematic diagram of the internal structure of the tank of the present utility model;

Figure 4 is a schematic diagram of the second structure of the utility model's junction motor.

In the picture: 1. Tank; 2. Control panel; 3. Feet; 4. Aeration pipe; 5. Filling port; 6. Air outlet; 7. Crushing box; 8. Water inlet; 9. Motor one; 10. Rotating shaft; 11. Pulley; 12. Crushing roller; 13. Water outlet; 14. Control valve; 15. Water collection cap; 16. Water distribution cap; 17. Iron-carbon packing layer; 18. Aerator; 19. Connection Horizontal plate; 20, partition plate; 21, motor two; 22, connecting pipe; 23, rotating shaft; 24, connecting plate; 25, cleaning brush.

Detailed ways

Preferred embodiments of the present utility model will be described below in conjunction with the accompanying drawings. It should be understood that the preferred embodiments described here are only used to illustrate and explain the utility model, and are not intended to limit the utility model.

Example: As shown in Figure 1-2, a device for treating sewage with an iron-carbon micro-electrolysis composite biofilm. The tank 1 is the main working part of the device for treating sewage with an iron-carbon micro-electrolysis composite biofilm, and a tank 1 is installed on the top. Crushing box 7; the crushing assembly consists of a crushing box 7, a motor 9, a rotating shaft 10, a pulley 11 and a crushing roller 12. The feet 3 at the four corners of the bottom support the tank 1. Personnel can use the control panel 2 to control the device. To operate, the sewage is connected to the inside from the water inlet 8 at the top, and then the sewage enters the crushing box 7. Start the motor 9, and the rotating shaft 10 rotates with the driving of the motor 9. Since the crushing roller 12 is connected to the rotating shaft 10 One end of the end, and the two sets of crushing rollers 12 are connected to the belt through the pulley 11, so that the two sets of crushing rollers 12 rotate simultaneously under the drive of the motor 9 to crush the impurities in the sewage, and then the sewage after crushing is completed Enter the tank 1 for processing.

As shown in Figure 3-4, the cleaning assembly consists of motor 21, rotating shaft 23, connecting plate 24 and cleaning brush 25. The crushed sewage enters the connecting pipe 22 from the through hole at the bottom of the crushing box 7, and then the sewage is introduced below The bottom of the partition plate 20 connects oxygen to the aeration pipe 4, so that the oxygen flows into the tank 1 from the multiple groups of aerators 18 on the surface of the aeration pipe 4, and the multiple groups of water distribution caps 16 guide the sewage into the iron-carbon The filling layer 17 is processed inside. After the treatment, the water source is led out through the water collection cap 15, and the control valve 14 on the surface of the water outlet 13 is opened, so that the water source is discharged from the water outlet 13, and the gas is discharged through the air outlet 6. The filling port 5 is used for The iron-carbon filler is added to the interior, and the connecting horizontal plate 19 is used to fix the second motor 21. The second motor 21 can be started later, and the rotating shaft 23 rotates with the driving of the second motor 21, causing the connecting plate 24 installed at one end to rotate, and the cleaning brush at the bottom 25 is constantly in contact with the surface of the aerator 18 during the rotation process to clear the blocked aeration holes.

Working principle: First, the sewage is connected to the inside from the water inlet 8 at the top, and then the sewage enters the crushing box 7. Start the motor 19, and the rotating shaft 10 rotates with the driving of the motor 9. Since the crushing roller 12 is connected to the rotation One end of the shaft 10, and the two sets of crushing rollers 12 are connected to the belt through the pulley 11, so that the two sets of crushing rollers 12 rotate simultaneously under the drive of the motor 19 to crush the impurities in the sewage, and then the sewage passes through the connected The pipe 22 is introduced into the bottom of the lower partition plate 20, and the oxygen is connected to the aeration pipe 4, so that the oxygen flows into the tank 1 from the multiple groups of aerators 18 on the surface of the aeration pipe 4, and the multiple groups of water distribution caps 16 will The sewage is introduced into the iron-carbon packing layer 17 for treatment. After the treatment, the water source is led out through the water collection cap 15, and the control valve 14 on the surface of the water outlet 13 is opened, so that the water source is discharged from the water outlet 13, and the gas is discharged through the air outlet 6.

Claims (6)

1. An apparatus for treating sewage by using an iron-carbon micro-electrolysis composite biological membrane is characterized by comprising:

the tank body (1) is a main working part of the iron-carbon micro-electrolysis composite biological membrane sewage treatment device, and the top of the tank body is provided with a crushing box (7);

a water inlet (8) installed at the top center of the pulverizing box (7);

a first motor (9) mounted on one side of the surface of the pulverizing box (7);

a rotating shaft (10) which is arranged inside the crushing box (7) and is connected to the output end of the motor I (9);

a crushing roller (12) connected to one end of the rotating shaft (10), and two groups of crushing rollers (12) are connected with a belt through a belt pulley (11);

a connection cross plate (19) installed below the inside of the tank (1);

a second motor (21) installed at the center of the bottom of the connection cross plate (19);

the rotating shaft (23) is connected to the output end of the motor II (21), and a connecting plate (24) is arranged at one end of the rotating shaft (23);

the cleaning brushes (25) are equidistantly distributed at one end of the connecting plate (24).

2. The device for treating sewage by using the iron-carbon micro-electrolysis composite biological membrane according to claim 1, wherein the tank (1) further comprises:

legs (3) which are arranged at four corners of the bottom of the tank body (1);

the control panel (2) is arranged on the surface of the tank body (1), and the control panel (2) is electrically connected with the first motor (9) and the second motor (21) respectively.

3. The device for treating sewage by using the iron-carbon micro-electrolysis composite biological membrane according to claim 1, wherein the tank (1) further comprises:

an aerator pipe (4) which is installed below the surface of the tank (1) and extends into the tank (1);

an aerator (18) which is equidistantly arranged on the top of the aerator pipe (4) and is contacted with the cleaning brush (25).

4. The device for treating sewage by using the iron-carbon micro-electrolysis composite biological membrane according to claim 1, wherein the tank (1) further comprises:

a partition plate (20) which is installed inside the tank body (1), and the two-component partition plate (20) partitions the inside into an iron-carbon packing layer (17);

and the filling port (5) is arranged on the surface of the tank body (1) and is communicated with the iron-carbon filling layer (17).

5. The device for treating sewage by using the iron-carbon micro-electrolysis composite biological membrane according to claim 1, wherein the tank (1) further comprises:

a water receiving cap (15) which is installed inside the tank body (1) and is connected with the upper partition board (20);

the water distribution cap (16) is arranged in the tank body (1) and is connected with the lower partition board (20).

6. The device for treating sewage by using the iron-carbon micro-electrolysis composite biological membrane according to claim 1, wherein the tank (1) further comprises:

the air outlet (6) is arranged above the surface of the tank body (1) and is communicated with the tank body (1);

a communicating pipe (22) connected to the inside of the tank (1) and communicating with the pulverizing box (7);

and the water outlet (13) is arranged above the surface of the tank body (1), and a control valve (14) is arranged on the surface of the water outlet (13).