CN212269567U - Oxygen increasing machine - Google Patents
Oxygen increasing machine Download PDFInfo
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- CN212269567U CN212269567U CN201922123792.2U CN201922123792U CN212269567U CN 212269567 U CN212269567 U CN 212269567U CN 201922123792 U CN201922123792 U CN 201922123792U CN 212269567 U CN212269567 U CN 212269567U
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- controller
- microbial inoculum
- remote control
- control signal
- aerator
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02W—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO WASTEWATER TREATMENT OR WASTE MANAGEMENT
- Y02W10/00—Technologies for wastewater treatment
- Y02W10/10—Biological treatment of water, waste water, or sewage
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Abstract
The utility model aims at providing an aerator, which comprises a ship body, wherein a propeller for providing power for the ship body is arranged on the ship body; the n support rods are uniformly arranged on the left side and the right side of the ship body and are vertical to the extending direction of the ship body; a microbial inoculum machine, comprising: the microbial inoculum tank is positioned on the ship body; the microbial inoculum nozzles are respectively arranged at the tail ends of the n support rods and are communicated with the microbial inoculum tank; the n oxygen increasing machines are respectively arranged beside the n microbial inoculum nozzles; and the control device is used for receiving the remote control signal and is in data connection with the propeller, the microbial inoculum machine and the controller of the aerator so as to control the running state of the ship body, whether the microbial inoculum machine sprays or not and whether the aerator is used or not. Solves the problem of long fermentation period of the prior oxidation pond.
Description
[ technical field ] A method for producing a semiconductor device
The utility model belongs to the technical field of sewage treatment, concretely relates to oxygen-increasing machine.
[ background of the invention ]
The old name of the stabilization pond is oxidation pond or biological pond, which is a general name of a structure for treating sewage by utilizing natural purification capacity. The purification process is similar to the self-purification process of natural water. The land is usually trimmed by a suitable worker to create a pond, and a dike and an impermeable layer are arranged to treat the sewage by means of microorganisms growing in the pond. The combined action of bacteria and algae is mainly utilized to treat organic pollutants in the wastewater. In our country, especially in the area of water shortage and drought, the biological oxidation pond is an effective method for implementing resource utilization of sewage, so that the treatment of sewage by a stable pond becomes a new technology which is vigorously popularized in our country. However, the oxidation pond belongs to anaerobic fermentation, the fermentation period is long, and no effective oxygenation means exists in the prior art.
[ Utility model ] content
The utility model aims at providing an oxygen-increasing machine to solve the problem that current oxidation pond fermentation period is long.
The utility model adopts the following technical scheme: an aerator, comprising:
the ship body is provided with a propeller for providing power for the ship body;
the n support rods are uniformly arranged on the left side and the right side of the ship body and are vertical to the extending direction of the ship body;
a microbial inoculum machine, comprising:
the microbial inoculum tank is positioned on the ship body;
the microbial inoculum nozzles are respectively arranged at the tail ends of the n support rods and are communicated with the microbial inoculum tank;
the n oxygen increasing machines are respectively arranged beside the n microbial inoculum nozzles;
and the control device is used for receiving the remote control signal and is in data connection with the propeller, the microbial inoculum machine and the controller of the aerator so as to control the running state of the ship body, whether the microbial inoculum machine sprays or not and whether the aerator is used or not.
The system further comprises a remote control signal sending end, wherein the remote control signal sending end is a remote controller or a client, and the client is a mobile phone, a computer or a vehicle-mounted terminal.
Further, when the remote control signal transmitting terminal is a remote controller, the control device includes:
a receiver for receiving remote control signals sent by the remote controller;
the controller is in data connection with the receiver and is used for receiving the remote control signal sent by the receiver;
the 4G intelligent terminal is in data interaction with the controller;
the execution unit is in data interaction with the controller and is used for receiving the control instruction sent by the controller and transmitting the control instruction to the aerator, the propeller, the microbial inoculum machine and the engine;
the 4G intelligent terminal is used for receiving the remote control signal sent by the controller and judging whether the ship information contained in the remote control signal is consistent with the ship information controlled by the execution unit: when the information is consistent, the remote control signal is returned to the controller and then sent to the execution unit for subsequent action; and when the information is inconsistent, a signal that the information is wrong is fed back to the controller.
Further, when the remote control signal transmitting terminal is a client, the control device includes:
the 4G intelligent terminal is used for receiving the remote control signal sent by the client;
the controller is in data interaction with the 4G intelligent terminal;
the execution unit is in data interaction with the controller and is used for receiving the control instruction sent by the controller and transmitting the control instruction to the aerator, the propeller, the microbial inoculum machine and the engine;
the 4G intelligent terminal is used for judging the received remote control signal and judging whether the ship information contained in the remote control signal is consistent with the ship information controlled by the execution unit: when the information is consistent, the remote control signal is sent to the controller and then sent to the execution unit for subsequent action; and when the information is inconsistent, feeding back a fault signal to the client.
Furthermore, a plurality of cameras are installed on the ship body, and each camera is connected to the 4G intelligent terminal in a data mode and is used for monitoring the working states of the ship body, the propeller, the microbial inoculum machine and the aerator respectively and feeding back the state information to the client through the 4G intelligent terminal.
Further, an engine and a generator are arranged on the ship body, and the engine is used for driving the generator to generate electricity and supplying electric energy to the aerator and the microbial inoculum machine.
The utility model has the advantages that: the utility model combines the aerator with the microbial inoculum machine, is arranged on the boat-shaped carrier, carries the aerator and the microbial inoculum machine to operate on the surface of the pond through the boat body, sprays the microbial inoculum and aerates the sewage in the pond, and greatly shortens the fermentation period; meanwhile, the remote control device and the monitoring equipment are matched, so that remote man-machine monitoring is realized.
[ description of the drawings ]
Fig. 1 is a schematic structural view of the present invention;
fig. 2 is a schematic diagram of the connection relationship of the control modules of the present invention.
The system comprises a ship body 1, an engine 2, an aerator 3, a microbial inoculum machine 4, a generator 5, a microbial inoculum tank 6, a receiver 7, a camera 8, a propeller 9, a controller 10, a support rod 11, a 12.4G intelligent terminal 13, a client, a remote controller 14 and an execution unit 15.
[ detailed description ] embodiments
The present invention will be described in detail with reference to the accompanying drawings and specific embodiments.
The utility model provides an oxygen-increasing machine, as shown in figure 1, including a operation carrier, hull 1 promptly is provided with the propeller 9 that provides power for hull 1 on it, still is provided with microbial inoculum machine, oxygen-increasing machine 3 and controlling means. A plurality of support bars 11 perpendicular to the hull 1 are provided on both sides of the hull 1 on average. The microbial inoculum machine 4 comprises a microbial inoculum tank 6 and a microbial inoculum sprayer communicated with the microbial inoculum tank, the microbial inoculum tank 6 is placed on the ship body 1, pipelines of a plurality of microbial inoculum sprayers are respectively arranged along the supporting rod 11, and the microbial inoculum sprayer is arranged at the tail end of the supporting rod 11. The number of the oxygen increasing machines 3 is the same as that of the microbial inoculum nozzles, and the oxygen increasing machines are arranged beside the microbial inoculum nozzles, so that oxygen can be increased at the positions where the microbial inoculum is sprayed, and the fermentation can be completed quickly. A plurality of cameras 8 are installed on the ship body 1, each camera 8 is connected to a 4G intelligent terminal 12 in a data mode, the model number of the 4G intelligent terminal 12 is GRM533QW, the cameras are respectively used for monitoring the working states of the ship body 1, the propeller 9, the microbial inoculum machine 4 and the aerator 3, and state information is fed back to the client 13 through the control device. The boat body 1 is also provided with an engine 2 and a generator 5, and the engine 2 is used for driving the generator 5 to generate electricity and supplying electric energy to the aerator 3 and the microbial inoculum machine 4.
The control device is used for receiving remote control signals and is in data connection with the propeller 9, the microbial inoculum machine and the aerator 3 so as to control the running state of the ship body 1, the information acquisition and collection of the camera 8, whether the microbial inoculum machine sprays or not and whether the aerator 3 is used or not. The remote control signal is from a remote control signal sending terminal, the remote control signal sending terminal is a remote controller 14 or a client terminal 13, the model of the remote controller 14 is D31S0-2Y, and the client terminal 14 is a mobile phone, a computer or a vehicle-mounted terminal.
As shown in fig. 2, when the remote control signal transmitting terminal is the remote controller 14, the control apparatus includes: a receiver 7 for receiving a remote control signal from a remote control 14; the controller 10 is in data connection with the receiver 7 and is used for receiving the remote control signal sent by the receiver 7, and the model of the controller is 200 Smart; the 4G intelligent terminal 12 is in data interaction with the controller 10; the execution unit 15 is in data interaction with the controller 10 and is used for receiving the control instruction sent by the controller 10 and transmitting the control instruction to the aerator 3, the propeller 9, the microbial inoculum machine 4 and the engine 2; the 4G intelligent terminal 12 is configured to receive the remote control signal sent by the controller 10, and determine whether ship information included in the remote control signal is consistent with the ship information controlled by the execution unit 5: when the information is consistent, the remote control signal is returned to the controller 10 and then sent to the execution unit 5 for subsequent action; when the information is inconsistent, a signal that the information is erroneous is fed back to the controller 10.
As shown in fig. 2, when the remote control signal transmitting end is the client 13, the control apparatus includes: the 4G intelligent terminal 12 is used for receiving the remote control signal sent by the client 13; the controller 10 is 200Smart in model and interacts with the 4G intelligent terminal 12 in data; the execution unit 15 is in data interaction with the controller 10 and is used for receiving the control instruction sent by the controller 10 and transmitting the control instruction to the aerator 3, the propeller 9, the microbial inoculum machine 4 and the engine 2; the 4G intelligent terminal 12 is configured to determine the received remote control signal, and determine whether ship information contained in the remote control signal is consistent with the ship information controlled by the execution unit 5: when the information is consistent, the remote control signal is sent to the controller 10 and then sent to the execution unit 5 for subsequent action; when the information is inconsistent, a failure signal is fed back to the client 13.
The utility model relates to an oxygen-increasing machine's working process does: an automatic aerator is arranged in the oxidation pond, the automatic aerator is remotely controlled through a remote controller or a client, and after the remote control signal is confirmed to correspond to the remote control signal, the remote controller can be used for controlling the running state of the automatic aerator, controlling whether the microbial inoculum machine 4 sprays microbial inoculum or not, controlling whether the automatic aerator 3 works or not and controlling the data acquisition and collection of the camera 8. By spraying the microbial inoculum into the oxidation pond and simultaneously using the aerator 3 for oxygenation, the fermentation period of sewage in the whole pond can be greatly shortened, and the production efficiency is improved. Meanwhile, the working state of the aerator can be observed in real time through the camera 8, and the equipment working or fault state of the aerator can be known remotely.
Claims (6)
1. An aerator, characterized in that it comprises:
a ship body (1) provided with a propeller (9) for providing power for the ship body (1);
the n support rods (11) are uniformly arranged on the left side and the right side of the ship body (1) and are vertical to the extending direction of the ship body (1);
a bacterial agent machine (4) comprising:
the microbial inoculum tank (6) is positioned on the ship body (1);
the microbial inoculum sprayers are respectively arranged at the tail ends of the n support rods (11) and are communicated with the microbial inoculum tank (6);
the n oxygen increasing machines (3) are respectively arranged beside the n microbial inoculum nozzles;
and the control device is used for receiving remote control signals and is in data connection with the propeller (9), the microbial inoculum machine and the controller of the aerator (3) so as to control the running state of the ship body (1), whether the microbial inoculum machine sprays or not and whether the aerator (3) is used or not.
2. The aerator according to claim 1, further comprising a remote control signal transmitting end, wherein the remote control signal transmitting end is a remote controller (14) or a client (13), and the client (13) is a mobile phone, a computer or a vehicle-mounted terminal.
3. The aerator according to claim 2, wherein when the remote control signal transmitter is a remote controller (14), the control device comprises:
a receiver (7) for receiving a remote control signal from said remote control (14);
the controller (10) is in data connection with the receiver (7) and is used for receiving the remote control signal sent by the receiver (7);
the 4G intelligent terminal (12) is in data interaction with the controller (10);
the execution unit (15) is in data interaction with the controller (10) and is used for receiving the control instruction sent by the controller (10) and transmitting the control instruction to the aerator (3), the propeller (9), the microbial inoculum machine (4) and the engine (2);
the 4G intelligent terminal (12) is used for receiving the remote control signal sent by the controller (10) and judging whether the ship information contained in the remote control signal is consistent with the ship information controlled by the execution unit (15): when the information is consistent, the remote control signal is returned to the controller (10) and then is sent to the execution unit (15) for subsequent action; when the information is inconsistent, a signal that the information is erroneous is fed back to the controller (10).
4. The aerator according to claim 2 or 3, wherein when the remote control signal transmitter is a client (13), the control device comprises:
the 4G intelligent terminal (12) is used for receiving the remote control signal sent by the client (13);
the controller (10) is in data interaction with the 4G intelligent terminal (12);
the execution unit (15) is in data interaction with the controller (10) and is used for receiving the control instruction sent by the controller (10) and transmitting the control instruction to the aerator (3), the propeller (9), the microbial inoculum machine (4) and the engine (2);
the 4G intelligent terminal (12) is used for judging the received remote control signal and judging whether the ship information contained in the remote control signal is consistent with the ship information controlled by the execution unit (15): when the information is consistent, the remote control signal is sent to the controller (10) and then sent to the execution unit (15) for subsequent action; and when the information is inconsistent, feeding back a fault signal to the client (13).
5. The aerator according to claim 3, wherein a plurality of cameras (8) are mounted on the hull (1), and each camera (8) is connected to the 4G intelligent terminal (12) for monitoring the working states of the hull (1), the propeller (9), the microbial inoculum machine (4) and the aerator (3), and feeding back the state information to the client (13) through the 4G intelligent terminal (12).
6. The aerator according to any one of claims 1 to 3, wherein an engine (2) and a generator (5) are further arranged on the hull (1), and the engine (2) is used for driving the generator (5) to generate electricity and supplying the electricity to the aerator (3) and the microbial inoculum machine (4).
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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CN201922123792.2U CN212269567U (en) | 2019-12-02 | 2019-12-02 | Oxygen increasing machine |
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CN201922123792.2U CN212269567U (en) | 2019-12-02 | 2019-12-02 | Oxygen increasing machine |
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN110759463A (en) * | 2019-12-02 | 2020-02-07 | 聂麒曌 | Oxygen increasing machine |
CN112799410A (en) * | 2021-03-31 | 2021-05-14 | 佛山市玉凰生态环境科技有限公司 | Automatic cruise control method and device for river sewage equipment, storage medium and terminal |
-
2019
- 2019-12-02 CN CN201922123792.2U patent/CN212269567U/en active Active
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN110759463A (en) * | 2019-12-02 | 2020-02-07 | 聂麒曌 | Oxygen increasing machine |
CN112799410A (en) * | 2021-03-31 | 2021-05-14 | 佛山市玉凰生态环境科技有限公司 | Automatic cruise control method and device for river sewage equipment, storage medium and terminal |
CN112799410B (en) * | 2021-03-31 | 2021-07-06 | 佛山市玉凰生态环境科技有限公司 | Automatic cruise control method and device for river sewage equipment, storage medium and terminal |
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