CN214087915U - Energy-saving automatic sewage treatment aeration device - Google Patents

Abstract

The utility model discloses an energy-saving automatic sewage treatment aeration device, which comprises a main body component, wherein the main body component comprises a first base, an aeration tank, a control cabinet, a support plate, a mixing box and a second base; the upper surface welding of first base has the aeration tank, the upper surface of first base just is located one side welding of aeration tank has the switch board, the upper surface welding of first base has two backup pads, two the upper surface of backup pad all welds the mixing box. The utility model discloses a dissolved oxygen detector detects the inside sewage of aeration tank to data transmission to the controller that will detect, when the dissolved oxygen detector of sewage shows that the value is not when presetting control range, the controller can adjust the frequency of first air-blower, thereby control when aerating sewage, improve aeration blower operating stability, avoid the aeration rate too big or undersize, influence the aerobic section microbiological treatment effect, reduce the energy consumption medicine consumption.

Description

Energy-saving automatic sewage treatment aeration device

The technical field is as follows:

the utility model relates to a sewage treatment technical field specifically is an energy-conserving automatic sewage treatment aeration equipment.

Background art:

the sewage treatment is a process for purifying sewage to meet the water quality requirement of discharging the sewage into a certain water body or reusing the sewage, the sewage treatment is widely applied to various fields such as buildings, agriculture, traffic, energy, petrifaction, environmental protection, urban landscape, medical treatment, catering and the like, the sewage treatment also increasingly enters the daily life of common people, the sewage needs to be aerated in the sewage treatment process, the energy consumption and the drug consumption of the existing sewage treatment plant are high, and the difficulty in controlling dissolved oxygen is high; and the blower and the water inlet lift pump are large power consumption units, the using amount of sewage treatment agents is large, and the integral operation cost is increased.

The utility model has the following contents:

the utility model aims at providing an energy-conserving automatic sewage treatment aeration equipment to solve the problem that proposes in the above-mentioned background art.

The utility model discloses by following technical scheme implement: an energy-saving automatic sewage treatment aeration device, comprising:

the main body component comprises a first base, an aeration tank, a control cabinet, a supporting plate, a mixing box and a second base;

an aeration tank is welded on the upper surface of the first base, a control cabinet is welded on the upper surface of the first base and on one side of the aeration tank, two support plates are welded on the upper surface of the first base, and a mixing box is welded on the upper surfaces of the two support plates;

the aeration component comprises a first air blower, a first air inlet pipe, a rotating speed sensor, a first air outlet pipe and an air gauge;

a first air blower is installed on one side of the upper surface of the first base, an air inlet of the first air blower is communicated with a first air inlet pipe, an air outlet of the first air blower is communicated with a first air outlet pipe, one end, far away from the first air blower, of the first air outlet pipe penetrates through the lower portion of one side of the aeration tank, a rotating speed sensor is installed on the outer side wall of the first air blower, and an air gauge is installed on the outer side wall of the first air outlet pipe;

the recycling assembly comprises a second air blower, a connecting pipe, a second air inlet pipe, a second air outlet pipe, a worm, a rod body, a worm wheel, a first plate body and a motor;

the upper surface of the control cabinet is provided with a second air blower, an air inlet of the second air blower is communicated with a second air inlet pipe, the outer side wall of the second air inlet pipe is uniformly communicated with a connecting pipe, an air outlet of the second air blower is communicated with a second air outlet pipe, one end, far away from the second air blower, of the second air outlet pipe penetrates through the upper surface of the mixing box, one side of one supporting plate is welded with a first plate body, the upper surface of the first plate body is provided with a motor, the output end of the motor is welded with a worm wheel, the lower surface of the mixing box is provided with a worm, the top of the worm penetrates through the lower surface of the mixing box, the worm is meshed with the worm wheel, and the outer side wall of the worm is uniformly welded with a rod body;

the control assembly comprises a controller, a signal emitter, a detection head, a dissolved oxygen detector, a signal receiver and a computer;

the controller is installed on the bottom wall inside the control cabinet, the signal transmitter is installed inside the control cabinet, the dissolved oxygen detector is installed inside the control cabinet, the detection head is installed on one side of the dissolved oxygen detector, one end of the detection head penetrates through the inner side wall of the control cabinet and one side of the control cabinet, the signal receiver is installed on one side of the upper surface of the second base, the computer is installed on the upper surface of the second base, the air gauge, the rotating speed sensor and the signal output end of the dissolved oxygen detector are in signal connection with the signal input end of the controller through wires, the electrical output end of the controller is in electrical connection with the electrical input ends of the first air blower, the second air blower, the motor and the signal transmitter through wires, and the signal output end of the signal transmitter is in signal connection with the signal input end of the signal receiver through wires, and the signal output end of the signal receiver is in signal connection with the signal input end of the computer through a lead.

As further preferable in the present technical solution: the bottom of worm rotates and is connected with the sleeve pipe, the lower surface welding of sleeve pipe has the second plate body.

As further preferable in the present technical solution: the lower surface symmetry welding of second plate body has two springs, two the bottom of spring all welds in the upper surface of first base.

As further preferable in the present technical solution: one side intercommunication of switch board has the blow off pipe, first valve is installed to the lateral wall of blow off pipe.

As further preferable in the present technical solution: one side intercommunication of mixing box has the second valve, the drain pipe is installed to the lateral wall of second valve.

As further preferable in the present technical solution: the front surface of the control cabinet is hinged with a door body, and a handle is welded on the front surface of the door body.

The utility model has the advantages that:

1. the utility model discloses a dissolved oxygen detector detects the inside sewage of aeration tank to data transmission to the controller that will detect, when the dissolved oxygen detector of sewage shows that the value is not when presetting control range, the controller can adjust the frequency of first air-blower, thereby control when aerating sewage, improve aeration blower operating stability, avoid the aeration rate too big or undersize, influence the aerobic section microbiological treatment effect, reduce the energy consumption medicine consumption.

2. The utility model discloses at the during operation, speed sensor measures the rotational speed of first air-blower, and the anemometer detects first air-blower exhaust amount of wind, and on data transmission to the controller after speed sensor and anemometer detected, the controller passed through the control signal transmitter and sends the signal, the signal receiver received signal on the second base to give the computer with data transmission, the operational aspect of first air-blower can be known in real time to the staff.

3. The utility model discloses to sewage aeration during operation, the work of controller control second air-blower, the inside gas absorption that inside production of aeration tank was arrived side by side to the mixing box of connecting pipe and second air-supply line, the motor drives the worm wheel and rotates, drives worm and the body of rod rotation during the worm wheel rotates, will arrange into the inside water of mixing box in advance and stir, the inside gas and the water intensive mixing of mixing box, during the gas of avoiding producing directly discharged the air, the condition that causes the pollution to the air appears.

Description of the drawings:

in order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

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

fig. 2 is a schematic view of a connection structure between the second base and the signal receiver in the present invention;

FIG. 3 is a front view of the present invention;

FIG. 4 is a schematic view of the connection structure between the middle support plate and the first base of the present invention;

fig. 5 is a circuit diagram of the present invention.

In the figure: 10. a body assembly; 11. a first base; 12. an aeration tank; 13. a control cabinet; 14. a support plate; 15. a mixing box; 16. a blow-off pipe; 17. a first valve; 18. a second base; 19. a door body; 191. a handle; 20. an aeration assembly; 21. a first blower; 22. a first air inlet pipe; 23. a rotational speed sensor; 24. a first air outlet pipe; 25. a wind meter; 30. a recovery assembly; 31. a second blower; 32. a connecting pipe; 33. a sleeve; 34. a second air inlet pipe; 35. a second air outlet pipe; 36. a worm; 37. a rod body; 38. a drain pipe; 39. a second valve; 391. a worm gear; 392. a first plate body; 393. a second plate body; 394. a spring; 395. a motor; 40. a control component; 41. a controller; 42. a signal transmitter; 43. a detection head; 44. a dissolved oxygen detector; 45. a signal receiver; 46. a computer.

The specific implementation mode is as follows:

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. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Examples

Referring to fig. 1-5, the present invention provides a technical solution: an energy-saving automatic sewage treatment aeration device, comprising:

a main body assembly 10, wherein the main body assembly 10 comprises a first base 11, an aeration tank 12, a control cabinet 13, a support plate 14, a mixing box 15 and a second base 18;

an aeration tank 12 is welded on the upper surface of the first base 11, a control cabinet 13 is welded on the upper surface of the first base 11 and on one side of the aeration tank 12, two support plates 14 are welded on the upper surface of the first base 11, and a mixing box 15 is welded on the upper surfaces of the two support plates 14;

the aeration component 20, the aeration component 20 comprises a first blower 21, a first air inlet pipe 22, a rotating speed sensor 23, a first air outlet pipe 24 and an air gauge 25;

a first air blower 21 is installed on one side of the upper surface of the first base 11, an air inlet of the first air blower 21 is communicated with a first air inlet pipe 22, an air outlet of the first air blower 21 is communicated with a first air outlet pipe 24, one end, far away from the first air blower 21, of the first air outlet pipe 24 penetrates through the lower portion of one side of the aeration tank 12, a rotating speed sensor 23 is installed on the outer side wall of the first air blower 21, and an air gauge 25 is installed on the outer side wall of the first air outlet pipe 24;

the recycling assembly 30, the recycling assembly 30 includes a second blower 31, a connecting pipe 32, a second air inlet pipe 34, a second air outlet pipe 35, a worm 36, a rod body 37, a worm wheel 391, a first plate 392 and a motor 395;

a second air blower 31 is mounted on the upper surface of the control cabinet 13, an air inlet of the second air blower 31 is communicated with a second air inlet pipe 34, the outer side wall of the second air inlet pipe 34 is uniformly communicated with a connecting pipe 32, an air outlet of the second air blower 31 is communicated with a second air outlet pipe 35, one end, far away from the second air blower 31, of the second air outlet pipe 35 penetrates through the upper surface of the mixing box 15, a first plate body 392 is welded on one side of one supporting plate 14, a motor 395 is mounted on the upper surface of the first plate body 392, a worm wheel 391 is welded at the output end of the motor 395, a worm 36 is arranged on the lower surface of the mixing box 15, the top of the worm 36 penetrates through the lower surface of the mixing box 15, the worm 36 is meshed with the worm wheel 391, and a rod body 37 is uniformly welded on the outer side wall of the worm 36;

a control assembly 40, wherein the control assembly 40 comprises a controller 41, a signal emitter 42, a detection head 43, a dissolved oxygen detector 44, a signal receiver 45 and a computer 46;

the controller 41 is installed on the bottom wall inside the control cabinet 13, the signal emitter 42 is installed inside the control cabinet 13, the dissolved oxygen detector 44 is installed inside the control cabinet 13, the detection head 43 is installed on one side of the dissolved oxygen detector 44, one end of the detection head 43 penetrates through the inner side wall of the control cabinet 13 and one side of the control cabinet 13, the signal receiver 45 is installed on one side of the upper surface of the second base 18, the computer 46 is installed on the upper surface of the second base 18, the air gauge 25, the rotation speed sensor 23 and the signal output end of the dissolved oxygen detector 44 are in signal connection with the signal input end of the controller 41 through wires, the electrical output end of the controller 41 is in electrical connection with the electrical input ends of the first air blower 21, the second air blower 31, the motor 395 and the signal emitter 42 through wires, the signal output end of the signal emitter 42 is in signal connection with the signal input end of the signal receiver 45 through wires, the signal output end of the signal receiver 45 is connected with the signal input end of the computer 46 through a lead in a signal connection mode.

In this embodiment, specifically: the bottom of the worm 36 is rotatably connected with a sleeve 33, and the lower surface of the sleeve 33 is welded with a second plate 393; by the arrangement of the sleeve 33 and the second plate 393, the sleeve 33 and the second plate 393 are moved when the worm 36 moves downward, and the second plate 393 slides between the two support plates 14, thereby guiding the worm 36.

In this embodiment, specifically: the two springs 394 are symmetrically welded to the lower surface of the second plate 393, and the bottoms of the two springs 394 are welded to the upper surface of the first base 11; due to the arrangement of the spring 394, when the second plate 393 moves downward, the spring 394 is pressed, and the spring 394 is deformed to buffer the second plate 393.

In this embodiment, specifically: one side of the aeration tank 12 is communicated with a sewage discharge pipe 16, and the outer side wall of the sewage discharge pipe 16 is provided with a first valve 17; by setting the sewage pipe 16 and the first valve 17, the first valve 17 is opened, and sewage can be discharged to the inside of the sewage pipe 16 through the sewage pipe 16.

In this embodiment, specifically: one side of the mixing box 15 is communicated with a second valve 39, and the outer side wall of the second valve 39 is provided with a drain pipe 38; through the arrangement of the second valve 39 and the drain pipe 38, the second valve 39 is opened, and the water mixed with the waste gas is discharged through the drain pipe 38.

In this embodiment, specifically: a door body 19 is hinged to the front surface of the control cabinet 13, and a handle 191 is welded to the front surface of the door body 19; through the arrangement of the door body 19 and the handle 191, the handle 191 is pulled to open the door body 19, so that the maintenance and replacement of elements inside the control cabinet 13 are facilitated for workers.

In the embodiment, the first air blower 21 and the second air blower 31 are JS-003, the rotation speed sensor 23 is HCNJ-104, the air gauge 25 is TES-1341, the motor 395 is TC-100L1-4, the controller 41 is QDY30A-N, and the signal transmitter 42 is CF-WU 780N; the dissolved oxygen detector 44 is of the type MIK-DY2900, and the signal receiver 45 is of the type TL-WA933 RE.

Working principle or structural principle, when in use, a worker opens the first valve 17, sewage to be aerated is discharged into the aeration tank 12 through the sewage discharge pipe 16, the dissolved oxygen detector 44 detects the sewage in the aeration tank 12 and transmits detected data to the controller 41, the controller 41 controls the first air blower 21 to be started, the first air inlet pipe 22 sucks external air and discharges the air into the aeration tank 12 through the first air outlet pipe 24, the sewage and the air in the aeration tank 12 are mixed, so that the sewage is aerated, the rotating speed sensor 23 measures the rotating speed of the first air blower 21, the air gauge 25 detects the air quantity discharged by the first air blower 21, the data detected by the rotating speed sensor 23 and the air gauge 25 are transmitted to the controller 41, the controller 41 sends signals through the control signal transmitter 42, the signal receiver 45 on the second base 18 receives the signals, and data is transmitted to a computer 46, when the display value of the dissolved oxygen detector 44 of the sewage is not within the preset control range, the controller 41 can adjust the frequency of the first blower 21, when the aeration tank 12 starts aeration work on the sewage, the controller 41 controls the second blower 31 and the motor 395 to start, the gas generated inside the aeration tank 12 is absorbed through the connecting pipe 32 and the second air inlet pipe 34, and the gas is discharged into the mixing box 15 through the second air outlet pipe 35, the motor 395 drives the worm wheel 391 to rotate, the worm wheel 391 is meshed with the worm 36, the worm 36 and the rod body 37 are driven to rotate when the worm wheel 391 rotates, the water body which is discharged into the mixing box 15 in advance is stirred, the gas and the water body inside the mixing box 15 are fully mixed, the second valve 39 is opened, and the water body mixed with the gas is discharged through the water discharge pipe 38, which is convenient and practical.

The above description is only a preferred embodiment of the present invention, and should not be taken as limiting the invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (6)

1. An energy-saving automatic sewage treatment aeration device is characterized by comprising:

a main body assembly (10), wherein the main body assembly (10) comprises a first base (11), an aeration tank (12), a control cabinet (13), a support plate (14), a mixing box (15) and a second base (18);

an aeration tank (12) is welded on the upper surface of the first base (11), a control cabinet (13) is welded on the upper surface of the first base (11) and on one side of the aeration tank (12), two support plates (14) are welded on the upper surface of the first base (11), and a mixing box (15) is welded on the upper surfaces of the two support plates (14);

the aeration component (20), the aeration component (20) comprises a first air blower (21), a first air inlet pipe (22), a rotating speed sensor (23), a first air outlet pipe (24) and an air meter (25);

a first air blower (21) is installed on one side of the upper surface of the first base (11), an air inlet of the first air blower (21) is communicated with a first air inlet pipe (22), an air outlet of the first air blower (21) is communicated with a first air outlet pipe (24), one end, far away from the first air blower (21), of the first air outlet pipe (24) penetrates through the lower portion of one side of the aeration tank (12), a rotating speed sensor (23) is installed on the outer side wall of the first air blower (21), and an air gauge (25) is installed on the outer side wall of the first air outlet pipe (24);

the recycling assembly (30), the recycling assembly (30) comprises a second air blower (31), a connecting pipe (32), a second air inlet pipe (34), a second air outlet pipe (35), a worm (36), a rod body (37), a worm wheel (391), a first plate body (392) and a motor (395);

the upper surface of the control cabinet (13) is provided with a second air blower (31), an air inlet of the second air blower (31) is communicated with a second air inlet pipe (34), the outer side wall of the second air inlet pipe (34) is uniformly communicated with a connecting pipe (32), an air outlet of the second air blower (31) is communicated with a second air outlet pipe (35), one end, far away from the second air blower (31), of the second air outlet pipe (35) penetrates through the upper surface of the mixing box (15), one side of the supporting plate (14) is welded with a first plate body (392), the upper surface of the first plate body (392) is provided with a motor (395), the output end of the motor (395) is welded with a worm wheel (391), the lower surface of the mixing box (15) is provided with a worm (36), the top of the worm (36) penetrates through the lower surface of the mixing box (15), and the worm (36) is meshed with the worm wheel (391), the outer side wall of the worm (36) is uniformly welded with a rod body (37);

the control assembly (40), the said control assembly (40) includes the controller (41), signal emitter (42), detects the head (43), dissolved oxygen detector (44), signal receiver (45) and computer (46);

controller (41) are installed to the inside diapire of switch board (13), the internally mounted of switch board (13) has signal transmitter (42), the internally mounted of switch board (13) has dissolved oxygen detector (44), detect head (43) are installed to one side of dissolved oxygen detector (44), the one end of detecting head (43) runs through the inside wall of switch board (13) with one side of switch board (13), signal receiver (45) are installed to upper surface one side of second base (18), the last surface mounting of second base (18) has computer (46), anemometer (25) tachometer (23) with the signal output part of dissolved oxygen detector (44) pass through the wire with the signal input part signal connection of controller (41), the electrical output part of controller (41) pass through the wire with first air-blower (21), The second air blower (31), the motor (395) and the electrical input end of the signal transmitter (42) are electrically connected, the signal output end of the signal transmitter (42) is in signal connection with the signal input end of the signal receiver (45) through a lead, and the signal output end of the signal receiver (45) is in signal connection with the signal input end of the computer (46) through a lead.

2. An energy-saving automatic sewage treatment aeration device according to claim 1, characterized in that: the bottom of worm (36) is rotated and is connected with sleeve pipe (33), the lower surface welding of sleeve pipe (33) has second plate body (393).

3. An energy-saving automatic sewage treatment aeration device according to claim 2, characterized in that: two springs (394) are symmetrically welded to the lower surface of the second plate body (393), and the bottoms of the two springs (394) are welded to the upper surface of the first base (11).

4. An energy-saving automatic sewage treatment aeration device according to claim 1, characterized in that: one side of the aeration tank (12) is communicated with a sewage discharge pipe (16), and a first valve (17) is arranged on the outer side wall of the sewage discharge pipe (16).

5. An energy-saving automatic sewage treatment aeration device according to claim 1, characterized in that: one side of the mixing box (15) is communicated with a second valve (39), and a drain pipe (38) is installed on the outer side wall of the second valve (39).

6. An energy-saving automatic sewage treatment aeration device according to claim 1, characterized in that: the front surface of the control cabinet (13) is hinged with a door body (19), and a handle (191) is welded on the front surface of the door body (19).

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