CN220231705U

CN220231705U - Shipborne water quality monitoring equipment

Info

Publication number: CN220231705U
Application number: CN202321713430.9U
Authority: CN
Inventors: 胡志国; 陆剑; 王昊昱; 刘显志; 王绪磊; 陈功; 杨艳; 杨永胜; 贲孝宇
Original assignee: Shanghai Yifeng Instrument Equipment Co ltd
Current assignee: Shanghai Yifeng Instrument Equipment Co ltd
Priority date: 2023-07-03
Filing date: 2023-07-03
Publication date: 2023-12-22
Anticipated expiration: 2033-07-03

Abstract

The utility model discloses shipborne water quality monitoring equipment which comprises a sensor group, a plurality of flow cells, flow meters, degassing tanks, control display members, a water pump, a water inlet pipe and a water outlet pipe, wherein one end of the water pump is connected with the water inlet pipe, the other end of the water pump is connected with one end of the flow meters through a pipeline, the other end of the flow meters is connected with the degassing tanks through the pipeline, the degassing tanks are connected with the flow cells through the water pipes, the sensor group is respectively connected with the corresponding flow cells, the flow cells are connected through the water pipes, the flow cells are connected with the water outlet pipe, and the sensor group is electrically connected with the control display members; the utility model is arranged on a civil ferry, and the water quality data at different positions is monitored by utilizing the navigation process of the ferry. And transmits the data to a remote data center.

Description

Shipborne water quality monitoring equipment

Technical Field

The utility model relates to the technical field of water quality monitoring, in particular to shipborne water quality monitoring equipment for a civil ferry.

Background

With the development of the age and the progress of society, the environment of rivers, lakes, reservoirs and oceans is more emphasized at present, the current water quality monitoring data are monitored by adopting sampling and fixed stations; if multipoint monitoring is needed, renting the ship to a designated site; part of the stations are in the field, and maintenance is relatively time-consuming, labor-consuming and money-consuming;

the civil ferry operates in rivers, lakes, reservoirs and oceans for a long time, the scheme utilizes the ship navigation process to carry out water quality on-site monitoring, and transmits the water quality measurement result to a data center, thereby providing high-efficiency and reliable data for environmental monitoring and supervision.

Disclosure of Invention

The utility model aims to provide civil ferry shipborne water quality monitoring equipment which is used for carrying out water quality on-site monitoring by utilizing the ship navigation process and transmitting a water quality measurement result to a data center.

The utility model solves the technical problems by adopting the following technical scheme: the shipborne water quality monitoring equipment comprises a sensor group, a plurality of flow cells, a flowmeter, degassing tanks, control display components, a water pump, a water inlet pipe and a water outlet pipe, wherein one end of the water pump is connected with the water inlet pipe, the other end of the water pump is connected with one end of the flowmeter through a pipeline, the other end of the flowmeter is connected with the degassing tanks through the pipeline, the degassing tanks are connected with the flow cells through the water pipes, the sensor group is respectively connected with the corresponding flow cells, the flow cells are connected through the water pipes, the flow cells are connected with the water outlet pipe, and the sensor group is electrically connected with the control display components;

the water pump is used for extracting a water sample to be detected through the water inlet pipe, the flowmeter is used for measuring the flow of the water sample extracted by the water pump flowing into the degassing tank, the degassing tank is used for degassing the water sample, the sensor assembly is used for monitoring the water sample in the flow cell and transmitting the monitoring result into the control display component, and the control display component is used for receiving the monitoring result and controlling the sensor assembly, the flowmeter, the degassing tank and the water pump to work.

Optionally, the sensor group is composed of a plurality of sensors, and a plurality of the sensors can respectively monitor the temperature, the salinity, the turbidity, the CDOM, the chlorophyll, the pH, the ORP, the dissolved oxygen, the algae species, the phycoerythrin, the phycocyanin and the oil in water.

Optionally, the control display component includes touch screen, control circuit box, water pump, sensor, degassing jar, flowmeter are connected with control circuit box electricity respectively, the electricity is connected between control circuit box and the touch screen.

Optionally, the water filter is arranged between the water inlet pipe and the water pump, one end of the water filter is connected to the water inlet pipe, and the other end of the water filter is connected with the water pump through a water pipe.

Optionally, the system further comprises a standby flow cell and a standby sensor, wherein the standby sensor is connected to the standby flow cell, one end of the standby flow cell is connected to the degassing tank through a water pipe, the other end of the standby flow cell is connected to the water outlet pipe through a water pipe, and the standby sensor is connected to the control circuit box through an electric connection.

Optionally, the number of the water outlet pipes is two, one water outlet pipe is connected to a corresponding one of the flow cells, and the other water outlet pipe is connected to the standby flow cell.

Optionally, the device further comprises a housing, wherein the sensor group, the plurality of flow cells, the flowmeter, the degassing tank, the control display member, the water pump, the water filter, the standby flow cell and the standby sensor are all installed in the housing, one end of the water inlet pipe extends out of the housing, and one ends of the two water outlet pipes extend out of the housing.

The utility model has the following beneficial effects:

1. the utility model is arranged on a civil ferry, and the water quality data at different positions is monitored by utilizing the navigation process of the ferry. And transmitting the data to a remote data center;

2. the navigation measurement obtains a large range of water quality data. The ferry is carried, so that daily routine monitoring can be realized.

Drawings

FIG. 1 is a schematic perspective view of the present utility model;

FIG. 2 is a schematic perspective view of one embodiment of the present utility model;

the labels in the figures are: 11-a sensor; 2-a flow cell; 3-a flow meter; 4-degassing tank; 5-controlling the display member; 6-a water pump; 7-a water inlet pipe; 8-a water outlet pipe; 9-a water filter; 10-a standby sensor; 20-a standby flow cell; 100-a housing; 51-a touch screen; 52-control circuit box.

Detailed Description

The technical scheme of the utility model is further described below with reference to the embodiment and the attached drawings.

Example 1

The embodiment provides shipborne water quality monitoring equipment, which comprises a sensor group, a plurality of flow cells 2, a flowmeter 3, a degassing tank 4, a control display member 5, a water pump 6, a water inlet pipe 7 and a water outlet pipe 8, wherein one end of the water pump 6 is connected with the water inlet pipe 7, the other end of the water pump is connected with one end of the flowmeter 3 through a pipeline, the other end of the flowmeter 3 is connected with the degassing tank 4 through a pipeline, the degassing tank 4 is connected with the flow cells 2 through a water pipe, the sensor group is respectively connected with the corresponding flow cells 2, the flow cells 2 are connected through the water pipe, the flow cells 2 are connected with the water outlet pipe 8, and the sensor group is electrically connected with the control display member 5;

the water pump 6 is used for extracting a water sample to be detected through the water inlet pipe 7, the flowmeter 3 is used for measuring the flow of the water sample extracted by the water pump 6 and flowing into the degassing tank 4, the degassing tank 4 is used for degassing the water sample, the sensor assembly is used for monitoring the water sample in the flow cell 2 and transmitting the monitoring result into the control display member 5, and the control display member 5 is used for receiving the monitoring result and controlling the operation of the sensor group, the flowmeter 3, the degassing tank 4 and the water pump 6.

The monitoring equipment is arranged on a civil ferry, monitors water quality data at different positions by utilizing the navigation process of the ferry, and sends the data to a remote data center.

In a further implementation manner of this embodiment, the sensor group is composed of a plurality of sensors 11, and the plurality of sensors 11 can respectively monitor the temperature, salinity, turbidity, CDOM, chlorophyll, pH, ORP, dissolved oxygen, algae species, phycoerythrin, phycocyanin, and oil in water of the water.

In a further implementation manner of this embodiment, the control display member 5 includes a touch screen 51 and a control circuit box 52, where the water pump 6, the sensor 11, the degassing tank 4 and the flowmeter 3 are respectively connected to the control circuit box 52, and the control circuit box 52 is electrically connected to the touch screen 51.

Further implementation manner of this embodiment, the water filter device further comprises a water filter 9, the water filter 9 is arranged between the water inlet pipe 7 and the water pump 6, one end of the water filter 9 is connected to the water inlet pipe 7, and the other end of the water filter 9 is connected with the water pump 6 through a water pipe.

Further implementation manner of this example, the device further comprises a standby flow cell 20 and a standby sensor 10, wherein the standby sensor 10 is connected to the standby flow cell 20, one end of the standby flow cell 20 is connected to the degassing tank 4 through a water pipe, the other end of the standby flow cell is connected to the water outlet pipe 8 through a water pipe, and the standby sensor 10 is connected to the control circuit box 52 through an electrical connection.

In a further implementation manner of this embodiment, the number of the water outlet pipes 8 is two, one water outlet pipe 8 is connected to a corresponding one of the flow cells 2, and the other water outlet pipe 8 is connected to the standby flow cell 20.

Further implementation manner of this embodiment further includes a housing 100, the sensor group, the plurality of flow cells 2, the flowmeter 3, the degassing tank 4, the control display member 5, the water pump 6, the water filter 9, the standby flow cell 20 and the standby sensor 10 are all installed in the housing 100, one end of the water inlet pipe 7 extends out of the housing 100, and one ends of the two water outlet pipes 8 extend out of the housing 100.

The sequence of the above embodiments is only for convenience of description, and does not represent the advantages and disadvantages of the embodiments.

Finally, it should be noted that: the above embodiments are only for illustrating the technical solution of the present utility model, and are not limiting; although the utility model has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present utility model.

Claims

1. The shipborne water quality monitoring equipment is characterized by comprising a sensor group, a plurality of flow cells, a flowmeter, degassing tanks, control display members, a water pump, a water inlet pipe and a water outlet pipe, wherein one end of the water pump is connected with the water inlet pipe, the other end of the water pump is connected with one end of the flowmeter through a pipeline, the other end of the flowmeter is connected with the degassing tanks through the pipeline, the degassing tanks are connected with the flow cells through the water pipes, the sensor group is respectively connected with the corresponding flow cells, the flow cells are connected through the water pipes, the flow cells are connected with the water outlet pipe, and the sensor group is electrically connected with the control display members;

2. The shipboard water quality monitoring device of claim 1, wherein the sensor group is comprised of a plurality of sensors, the plurality of sensors being capable of monitoring temperature, salinity, turbidity, CDOM, chlorophyll, pH, ORP, dissolved oxygen, algae species, phycoerythrin, phycocyanin, oil in water, respectively.

3. The shipborne water quality monitoring device of claim 2, wherein the control display member comprises a touch screen and a control circuit box, the water pump, the sensor, the degassing tank and the flowmeter are respectively and electrically connected with the control circuit box, and the control circuit box is electrically connected with the touch screen.

4. The shipboard water quality monitoring device of claim 3, further comprising a water filter disposed between the water inlet pipe and the water pump, wherein one end of the water filter is connected to the water inlet pipe, and the other end is connected to the water pump through a water pipe.

5. The shipborne water quality monitoring device of claim 4, further comprising a standby flow cell and a standby sensor, wherein the standby sensor is connected to the standby flow cell, one end of the standby flow cell is connected to the degassing tank through a water pipe, the other end of the standby flow cell is connected to the water outlet pipe through a water pipe, and the standby sensor is connected to the control circuit box through an electrical connection.

6. The on-board water quality monitoring apparatus of claim 5, wherein the number of water outlet pipes is two, one water outlet pipe is connected to a corresponding one of the flow cells, and the other water outlet pipe is connected to a spare flow cell.

7. The shipboard water quality monitoring device of claim 5, further comprising a housing, wherein the sensor set, the plurality of flow cells, the flow meter, the degassing tank, the control display member, the water pump, the water filter, the backup flow cell, and the backup sensor are all mounted in the housing, wherein one end of the water inlet pipe extends out of the housing, and wherein one ends of the two water outlet pipes extend out of the housing.