CN219363414U - Remote control reoxygenation system applied to lake - Google Patents

Abstract

The utility model discloses a remote control reoxygenation system applied to a lake, which comprises a 4G cloud platform, a PLC control system, a reoxygenation device and a water quality monitoring buoy station. According to the utility model, a plurality of groups of water quality monitoring floating stations are arranged, water quality data are issued to a 4G control module of a PLC control system through a 4G cloud platform, the 4G control module is connected with the PLC control system, after a water quality parameter instruction is obtained by the PLC control system, three-layer dissolved oxygen values corresponding to the water quality monitoring floating stations in a lake are analyzed, the height of corresponding movable pipe orifices is controlled according to the three-layer values, the dissolved oxygen values of all the floating stations are compared, the reoxygenation condition of all the movable pipe orifices is judged, the flow regulating and controlling device is controlled to regulate the flow of all the outlets, so that the effects of accurate fixed point reoxygenation and layered reoxygenation are achieved, the reoxygenation efficiency is improved, and the consumption of oxygen and electric energy is reduced.

Description

Remote control reoxygenation system applied to lake

Technical Field

The utility model relates to the technical field of reoxygenation, in particular to a remote control reoxygenation system applied to lakes.

Background

The ultra-nanometer gas-soluble reoxygenation system is mainly used for treating the water environment of the lake, improving the dissolved oxygen in the water, building the oxygen-enriched healthy habitat and recovering the biological diversity of the river and the lake. At present, lake reoxygenation devices are also available on the market, but the common reoxygenation devices cannot perform layered reoxygenation in the lake reoxygenation process, cannot perform remote monitoring, and can solve the problem of river and lake reoxygenation more accurately by failing to analyze data through a cloud system.

Disclosure of Invention

In order to overcome the defects of related products in the prior art, the utility model provides a remote control reoxygenation system applied to lakes.

The utility model provides a remote control reoxygenation system applied to a lake, which comprises: the system comprises a 4G cloud platform, a PLC control system, a reoxygenation device and a water quality monitoring buoy station; the reoxygenation device is connected with the water outlet pipe group, the water outlet pipe group comprises a plurality of groups of pipelines which are arranged in parallel, the pipelines are arranged in a lake in an extending mode, a movable pipe orifice which can be adjusted in a telescopic mode is arranged at a water outlet of each group of pipelines, each group of movable pipe orifice is provided with a group of water quality monitoring float stations, the water quality monitoring float stations are arranged on the water surface of the lake in a floating mode, and the space distance between the water quality monitoring float stations and the movable pipe orifice is 3-4m; the reoxygenation device is externally connected with a PLC control system, and the PLC control system and the water quality monitoring buoy station perform wireless data transmission with the 4G cloud platform; the reoxygenation device is also provided with a flow regulating device for monitoring and adjusting the flow.

In some embodiments of the utility model, the reoxygenation device comprises a submersible pump, a filter, a centrifugal booster pump, a gasifier device, a high-efficiency nano dissolved oxygen cone tank, a water separator, an air source and a pressure transmitter, wherein the submersible pump, the filter, the centrifugal booster pump, the high-efficiency nano dissolved oxygen cone tank and the water separator are sequentially communicated, the air source, the gasifier device and the high-efficiency nano dissolved oxygen cone tank are sequentially communicated, the high-efficiency nano dissolved oxygen cone tank is further provided with the pressure transmitter, and the air source is used for providing oxygen.

In certain embodiments of the utility model, the inlet of the submersible pump is provided with a water inlet grille.

In some embodiments of the present utility model, the water separator includes a plurality of water outlets, which are respectively connected to corresponding pipelines of the water outlet pipe group.

In certain embodiments of the present utility model, the flow regulating device comprises a check valve, an inlet regulating valve, a first electromagnetic flow meter, a pressure gauge, a pressure sensor, a safety valve, a composite exhaust valve, a gas flow regulating device, a first stop valve, a liquid level sensor, a second stop valve, an electric proportional regulating valve, and a second electromagnetic flow meter; the check valve and the inlet regulating valve are respectively arranged on the pipeline between the submersible pump and the filter; the submersible pump is also connected with a first electromagnetic flowmeter; the electromagnetic flowmeter, the pressure gauge, the pressure sensor and the composite exhaust valve are respectively arranged on a pipeline between the centrifugal booster pump and the high-efficiency nano dissolved oxygen cone tank; the high-efficiency nanometer dissolved oxygen cone tank is also connected with a safety valve; a first stop valve is arranged on a pipeline between the air source and the gasifier device; a gas flow regulating device is arranged on a pipeline between the high-efficiency nanometer dissolved oxygen cone tank and the gasifier device; and a second stop valve, an electric proportional control valve and a second electromagnetic flowmeter are respectively arranged on the pipeline of each group of water outlets of the water separator.

In some embodiments of the present utility model, the water quality monitoring buoy station includes a buoy station body, in which a data transmission module for wireless data transmission with the 4G cloud platform is built; the bottom of the buoy station body is provided with a telescopic adjusting rod with adjustable height, and a plurality of groups of DO probes are sequentially arranged on the telescopic adjusting rod from top to bottom at intervals.

In some embodiments of the utility model, the top cover of the buoy station body is provided with a light-transmitting cover, and a solar power supply module is arranged in the light-transmitting cover.

Compared with the prior art, the utility model has the following advantages:

according to the remote control reoxygenation system applied to the lake, a plurality of groups of water quality monitoring float stations are arranged, water quality data are transmitted to a 4G control module of a PLC control system through the 4G cloud platform, the 4G control module is connected with the PLC control system, after a water quality parameter instruction is obtained by the PLC control system, three layers of dissolved oxygen values corresponding to the water quality monitoring float stations in the lake are analyzed, the height of corresponding movable pipe orifices is controlled according to the three layers of values, the dissolved oxygen values of all the float stations are compared, reoxygenation conditions of all the movable pipe orifices are judged, and a flow regulating device is controlled to regulate the flow of all outlets, so that the effects of accurate fixed-point reoxygenation and layered reoxygenation are achieved, reoxygenation efficiency is improved, and consumption of oxygen and electric energy is reduced.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings that are needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present utility model, and other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic block diagram of a remote control reoxygenation system for lakes according to the present utility model;

FIG. 2 is a schematic structural view of the reoxygenation apparatus according to the present utility model;

FIG. 3 is a schematic structural view of the water quality monitoring buoy station of the utility model.

Reference numerals illustrate:

1. a 4G cloud platform; 2. a PLC control system; 3. a reoxygenation device; 4. a flow rate control device; 5. a water quality monitoring buoy station; 6. a water outlet pipe group; 31. a water inlet grille; 32. submersible pump; 33. a check valve; 34. an inlet regulating valve; 35. a filter; 36. a centrifugal pressurizing pump; 37. a first electromagnetic flowmeter; 38. a pressure gauge; 39. a pressure sensor; 310. a safety valve; 311. a composite exhaust valve; 312. a gas flow rate regulating device; 313. a gasifier arrangement; 314. a first stop valve; 315. a gas source; 316. a pressure transmitter; 317. an efficient nano dissolved oxygen cone tank; 318. a liquid level sensor; 41. a second shut-off valve; 42. an electric proportional control valve; 43. a second electromagnetic flowmeter; 44. a water outlet; 45. a water separator; 51. a float station body; 52. a telescopic adjusting rod; 53. a DO probe; 54. and the solar power supply module.

Detailed Description

In order to enable those skilled in the art to better understand the present utility model, the following description will make clear and complete descriptions of the technical solutions according to the embodiments of the present utility model with reference to the accompanying drawings. It is apparent that the described embodiments are only some embodiments of the utility model, but not all embodiments, and that the preferred embodiments of the utility model are shown in the drawings. This utility model may be embodied in many different forms and is not limited to the embodiments described herein, but rather is provided to provide a more thorough understanding of the present disclosure.

Referring to fig. 1, the remote control reoxygenation system applied to lakes comprises a 4G cloud platform 1, a PLC control system 2, a reoxygenation device 3 and a water quality monitoring float station 5; the reoxygenation device 3 is connected with the water outlet pipe group 6, the water outlet pipe group 6 comprises a plurality of groups of pipelines which are arranged in parallel, the pipelines are arranged in water bodies such as lakes in an extending mode, a water outlet 44 of each group of pipelines is provided with a movable pipe orifice which can be adjusted in a telescopic mode, each group of movable pipe orifices is provided with a group of water quality monitoring float stations 5, the water quality monitoring float stations 5 are arranged on the water surface of the lakes in a floating mode, and the space distance between the water quality monitoring float stations 5 and the movable pipe orifices is 3-4m; the reoxygenation device 3 is externally connected with a PLC control system 2, and the PLC control system 2 and the water quality monitoring float station 5 perform wireless data transmission with the 4G cloud platform 1; the reoxygenation device 3 is also provided with a flow regulating device 4 for monitoring and adjusting the flow. The water quality data collected by the water quality monitoring buoy station 5 is transmitted to the 4G cloud platform 1,4G cloud platform 1 through the 4G to send corresponding instructions to the PLC control system 2, the PLC control system 2 uploads all equipment data and instrument data to the 4G cloud platform 1,4G cloud platform 1, the operation of the whole system can be remotely monitored and controlled through intelligent terminal operation, and the intelligent terminal for operation can be a computer or a mobile terminal which are in wireless connection with the 4G cloud platform 1.

Referring to fig. 2, the reoxygenation device 3 includes a submersible pump 32, a filter 35, a centrifugal booster pump 36, a gasifier device 313, a high-efficiency nano dissolved oxygen cone tank 317, a water separator 45, an air source 315, and a pressure transmitter 316, wherein the submersible pump 32, the filter 35, the centrifugal booster pump 36, the high-efficiency nano dissolved oxygen cone tank 317, and the water separator 45 are sequentially communicated, the air source 315, the gasifier device 313, and the high-efficiency nano dissolved oxygen cone tank 317 are sequentially communicated, the high-efficiency nano dissolved oxygen cone tank 317 is further provided with the pressure transmitter 316, and the air source 315 is used for providing oxygen.

An inlet of the submersible pump 32 is provided with a water inlet grille 31; the water separator 45 comprises a plurality of groups of water outlets 44 which are respectively communicated with corresponding pipelines of the water outlet pipe group 6.

The flow regulating device 4 comprises a check valve 33, an inlet regulating valve 34, a first electromagnetic flowmeter 37, a pressure gauge 38, a pressure sensor 39, a safety valve 310, a composite exhaust valve 311, a gas flow regulating device 312, a first stop valve 314, a liquid level sensor 318, a second stop valve 41, an electric proportional regulating valve 42 and a second electromagnetic flowmeter 43; the check valve 33 and the inlet regulating valve 34 are respectively arranged on the pipeline between the submersible pump 32 and the filter 35; the submersible pump 32 is also connected with a first electromagnetic flowmeter 37; the electromagnetic flowmeter, the pressure gauge 38, the pressure sensor 39 and the composite exhaust valve 311 are respectively arranged on the pipeline between the centrifugal booster pump 36 and the high-efficiency nano dissolved oxygen cone tank 317; the high-efficiency nano dissolved oxygen cone tank 317 is also connected with a safety valve 310; a first shut-off valve 314 is arranged in the line between the gas source 315 and the gasifier arrangement 313; a gas flow regulating device 312 is arranged on a pipeline between the high-efficiency nano dissolved oxygen cone 317 and the gasifier device 313; the pipelines of each group of water outlets 44 of the water separator 45 are respectively provided with a second stop valve 41, an electric proportional control valve 42 and a second electromagnetic flowmeter 43.

Referring to fig. 3, the water quality monitoring buoy station 5 includes a buoy station body 51 that can be buoyed on the water surface, and a data transmission module for performing wireless data transmission with the 4G cloud platform 1 is disposed in the buoy station body 51; the bottom of the float station body 51 is provided with a telescopic adjusting rod 52 with adjustable height, and a plurality of groups of DO probes 53 are sequentially arranged on the telescopic adjusting rod 52 from top to bottom at intervals, for example, in the embodiment of the utility model, the number of the DO probes 53 is three, so that the number of three layers of dissolved oxygen can be correspondingly obtained, and according to actual requirements, the DO probes 53 with different intervals and different numbers can be also automatically arranged. In other embodiments of the present utility model, the top cover of the floating station body 51, which is located outside the water surface, is provided with a light-transmitting cover, and a solar power supply module 54 capable of storing solar energy for power supply is disposed in the light-transmitting cover.

According to the remote control reoxygenation system applied to the lake, a plurality of groups of water quality monitoring float stations 5 are arranged, water quality data are issued to a 4G control module of a PLC control system 2 through a 4G cloud platform 1,4G cloud platform 1, the 4G control module is connected with the PLC control system 2, after a water quality parameter instruction is obtained by the PLC control system 2, three layers of dissolved oxygen values corresponding to the water quality monitoring float stations 5 in the lake are analyzed, the height of corresponding movable pipe orifices is controlled according to the sizes of the three layers of the values, the dissolved oxygen values of all the float stations are compared, reoxygenation conditions of all the movable pipe orifices are judged, and a flow regulating device 4 is controlled to regulate the flow sizes of all the outlets, so that the effects of accurate fixed-point reoxygenation and layered reoxygenation are achieved, reoxygenation efficiency is improved, and consumption of oxygen and electric energy is reduced.

What is not described in detail in this specification is prior art known to those skilled in the art. Although the present utility model has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that the present utility model may be modified or equivalents substituted for some of the features thereof. All equivalent structures made by the content of the specification and the drawings of the utility model are directly or indirectly applied to other related technical fields, and are also within the scope of the utility model.

Claims (7)

1. Remote control reoxygenation system for lakes, characterized in that it comprises: the device comprises a 4G cloud platform (1), a PLC control system (2), a reoxygenation device (3) and a water quality monitoring floating station (5); the reoxygenation device (3) is connected with a water outlet pipe group (6), the water outlet pipe group (6) comprises a plurality of groups of pipelines which are arranged in parallel, the pipelines are arranged in a lake in an extending mode, a water outlet (44) of each group of pipelines is provided with a movable pipe orifice which can be adjusted in a telescopic mode, each group of movable pipe orifices is provided with a group of water quality monitoring floating stations (5), the water quality monitoring floating stations (5) are arranged on the water surface of the lake in a floating mode, and the space distance between the water quality monitoring floating stations (5) and the movable pipe orifices is 3-4m; the reoxygenation device (3) is externally connected with a PLC control system (2), and the PLC control system (2) and the water quality monitoring float station (5) perform wireless data transmission with the 4G cloud platform (1); the reoxygenation device (3) is also provided with a flow regulating device (4) for monitoring and adjusting the flow.

2. The remote control reoxygenation system for lakes of claim 1, wherein: the reoxygenation device (3) comprises a submersible pump (32), a filter (35), a centrifugal booster pump (36), a gasifier device (313), a high-efficiency nano dissolved oxygen cone tank (317), a water separator (45), an air source (315) and a pressure transmitter (316), wherein the submersible pump (32), the filter (35), the centrifugal booster pump (36), the high-efficiency nano dissolved oxygen cone tank (317) and the water separator (45) are sequentially communicated, the air source (315), the gasifier device (313) and the high-efficiency nano dissolved oxygen cone tank (317) are sequentially communicated, the high-efficiency nano dissolved oxygen cone tank (317) is further provided with the pressure transmitter (316), and the air source (315) is used for providing oxygen.

3. The remote control reoxygenation system for lakes of claim 2, wherein: an inlet of the submersible pump (32) is provided with a water inlet grid (31).

4. The remote control reoxygenation system for lakes of claim 2, wherein: the water separator (45) comprises a plurality of groups of water outlets (44) which are respectively communicated with corresponding pipelines of the water outlet pipe group (6).

5. The remote control reoxygenation system for lakes of claim 2, wherein: the flow regulating device (4) comprises a check valve (33), an inlet regulating valve (34), a first electromagnetic flowmeter (37), a pressure gauge (38), a pressure sensor (39), a safety valve (310), a composite exhaust valve (311), a gas flow regulating device (312), a first stop valve (314), a liquid level sensor (318), a second stop valve (41), an electric proportional regulating valve (42) and a second electromagnetic flowmeter (43); the check valve (33) and the inlet regulating valve (34) are respectively arranged on the pipeline between the submersible pump (32) and the filter (35); the submersible pump (32) is also connected with a first electromagnetic flowmeter (37); the electromagnetic flowmeter, the pressure gauge (38), the pressure sensor (39) and the composite exhaust valve (311) are respectively arranged on a pipeline between the centrifugal booster pump (36) and the high-efficiency nano dissolved oxygen cone tank (317); the high-efficiency nanometer dissolved oxygen cone tank (317) is also connected with a safety valve (310); a first stop valve (314) is arranged on a pipeline between the air source (315) and the gasifier device (313); a gas flow regulating device (312) is arranged on a pipeline between the high-efficiency nanometer dissolved oxygen cone tank (317) and the gasifier device (313); and a second stop valve (41), an electric proportional control valve (42) and a second electromagnetic flowmeter (43) are respectively arranged on the pipeline of each group of water outlets (44) of the water separator (45).

6. The remote control reoxygenation system for lakes of claim 1, wherein: the water quality monitoring floating station (5) comprises a floating station body (51), wherein a data transmission module for carrying out wireless data transmission with the 4G cloud platform (1) is arranged in the floating station body (51); the bottom of the buoy station body (51) is provided with a telescopic adjusting rod (52) with adjustable height, and a plurality of groups of DO probes (53) are sequentially arranged on the telescopic adjusting rod (52) from top to bottom at intervals.

7. The remote control reoxygenation system for lakes of claim 6, wherein: the top cover of the buoy station body (51) is provided with a light-transmitting cover, and a solar power supply module (54) is arranged in the light-transmitting cover.