CN206960462U - A kind of seawater quality optics on-line monitoring system - Google Patents

Abstract

The utility model discloses an optical online monitoring system for sea water quality, which comprises a control and data acquisition unit, a sensor measurement module, an air circuit unit and a water circuit unit; the control and data acquisition unit includes a host computer, a power supply and control module, and a data acquisition module and communication module; dissolved oxygen sensor, COD sensor, chlorophyll sensor and petroleum hydrocarbon sensor in water form a sensor measurement module; the advantages of the utility model: 1. Setting the defoamer can effectively eliminate the influence of air bubbles in the water sample on the test results; 2. The sensor is installed at an angle of 20°C to 85°C, which can effectively reduce the air bubbles attached to the light window and the impurities in the water sample to settle on the light window; 3. The system is equipped with a gas circuit, which regularly injects gas into the pipeline to clean the sensor light window , Impurities are discharged with water samples; 4. Real-time query of marine environmental information and dynamic release of monitoring information through wireless transmission can greatly improve the application level of marine monitoring data.

Description

A seawater quality optical on-line monitoring system

technical field

The utility model relates to the field of seawater quality detection, in particular to an optical on-line monitoring system for seawater quality.

technical background

With the rapid development of my country's national economy, my country's sea water environment has also suffered serious damage, especially the coastal water environment. The discharge of industrial wastewater and domestic sewage, increased navigation, and oil spills have caused a series of seawater quality problems. In the fields of aquaculture, environmental monitoring and scientific research, it is necessary to know the changes of various parameters in seawater in real time. At present, the traditional detection methods for various pollutants in seawater mainly rely on chemical methods and chemical reactions. Most of them are based on on-site sampling and laboratory analysis. Water samples need to be pretreated. The requirements of modern seawater monitoring; this type of analysis method is likely to pose a threat to the health of operators, the detection process needs to consume reagents, and the waste liquid generated is directly discharged into the environment, which is likely to cause secondary pollution and other problems.

Utility model content

Aiming at the cumbersome and time-consuming laboratory analysis and test steps in the existing seawater quality monitoring technology, the purpose of this utility model is to provide an online monitoring system for multi-parameter optical measurement of seawater body using wireless network transmission technology.

The technical scheme that the utility model adopts for realizing the above object is as follows:

An optical online monitoring system for sea water quality, comprising a control and data acquisition unit, a sensor measurement module, an air circuit unit and a water circuit unit; the control and data acquisition unit includes a host computer, a power supply and control module, a data acquisition module and a communication module; Dissolved oxygen sensor, COD sensor, chlorophyll sensor and petroleum hydrocarbon sensor in water constitute the sensor measurement module; the air circuit unit includes air compressor and check valve; the water circuit unit includes sample pump, water inlet, throttle valve, defoamer and drain;

The upper computer is electrically connected to the power supply and control module, and the power supply and control module is connected to the dissolved oxygen sensor, COD sensor, chlorophyll sensor, petroleum hydrocarbon sensor in water, sampling pump, and air compressor. The data acquisition module is connected to the dissolved oxygen sensor, COD Sensors, chlorophyll sensors, petroleum hydrocarbon sensors in water, and upper computer are electrically connected to communication modules;

The sampling pump is connected to the water inlet, the water inlet is a three-way type, and one road is connected to the throttle valve and the system drain in sequence; the other road is connected to the defoamer; the water outlet of the defoamer is connected to the COD sensor, chlorophyll The sensor and the petroleum hydrocarbon sensor in water are connected sequentially; the overflow port of the defoamer is connected with the system drain port;

The air compressor is respectively connected to the light window of the flow cell of the COD sensor flow cell, the dissolved oxygen sensor, the chlorophyll sensor and the petroleum hydrocarbon sensor in water through a one-way valve;

The dissolved oxygen sensor, COD sensor, chlorophyll sensor and petroleum hydrocarbon sensor in water are all installed at an angle of 20°C to 85°C.

The defoamer includes a defoamer shell, a partition, a defoamer water inlet, a defoamer drain, a defoamer outlet and a defoamer overflow; the water sample enters the defoamer from the defoamer water inlet , the defoaming treatment is carried out through the fixed route flow path of the partition, and the water sample after the defoaming treatment enters the test waterway through the outlet of the defoamer for testing; the overflow of the defoamer is connected with the system drain; the drain of the defoamer It is also communicated with the system drain through a switch.

The sampling pump is a peristaltic or submersible pump.

The upper computer controls the feeding of the sample pump through the power supply and control module, the water sample to be tested enters the pipeline through the water inlet, and the water sample to be tested is divided into two through a three-way waterway, one for testing, and the other for redundant The water sample is discharged through the drain port, and a throttle valve is added to the water circuit to control the drainage speed, thereby controlling the sampling speed of the measurement water circuit. The water sample first enters the dissolved oxygen sensor for the dissolved oxygen test. After the test is completed, it enters the defoamer to perform defoaming treatment on the water sample to eliminate the air bubbles in the water sample. After the defoaming treatment, the water sample enters the COD sensor, chlorophyll sensor and The petroleum hydrocarbon sensor in water is tested for COD, chlorophyll and petroleum hydrocarbon in water respectively, and the water samples after the test are discharged through the drain.

The defoamer includes a defoamer shell, a partition, a defoamer water inlet, a defoamer drain, a defoamer water outlet and a defoamer overflow. The water sample enters the defoamer from the water inlet of the defoamer, and undergoes defoaming treatment through the fixed route of the separator. The water sample after defoaming treatment enters the test waterway through the outlet of the defoamer for testing. The overflow port of the defoamer is reserved for the defoamer. When the water flow rate is too fast, the excess water sample is directly discharged from the defoamer through the overflow port, and discharged from the system through the system drain port. When the system stops working, some water samples will remain in the defoamer. At this time, turn on the switch of the drain outlet of the defoamer to discharge the water samples out of the defoamer and the system through the system drain.

The dissolved oxygen sensor, COD sensor, chlorophyll sensor and petroleum hydrocarbon sensor in water receive power supply and control module instructions for testing, and the data after the test is collected by the data acquisition module, and the collected data is finally displayed by the host computer or communicated Module transfer.

The communication module is a wireless communication module. Through wireless transmission and remote monitoring technology, users can query, monitor and save marine environmental information in real time through various network terminals.

The air compressor receives the power supply and the command of the control module to regularly feed gas into the COD sensor flow cell, dissolved oxygen, chlorophyll and water petroleum hydrocarbon sensor flow cell to clean the sensor light window. A one-way valve is added to the air circuit to prevent water samples from entering the air compressor.

The dissolved oxygen sensor, COD sensor, chlorophyll sensor and petroleum hydrocarbon sensor in water are all installed at an angle of 20°C to 85°C to avoid air bubbles attached to the light window of the sensor and impurities in the water sample to settle on the light window.

The utility model has the following advantages:

1. The system is equipped with a defoamer, which can effectively eliminate the influence of air bubbles in the water sample on the test results;

2. The sensor is installed at an angle of 20°C to 85°C, which can effectively reduce the air bubbles attached to the light window and the impurities in the water sample to settle on the light window;

3. The system is equipped with a gas circuit, and the gas is regularly injected into the pipeline to clean the sensor light window, and the impurities are discharged from the system along with the water samples;

4. The utility model is a remote wireless monitoring system. Through wireless transmission and remote monitoring technology, the three-dimensional monitoring of the marine environment is realized. Users can query the marine environment information in real time and dynamically release the monitoring information through various network terminals. Greatly improve the application level of marine monitoring data.

Description of drawings

Fig. 1 is the structural representation of the utility model system;

Fig. 2 is the structure schematic diagram of the system defoamer of the present utility model;

Fig. 3 is the structural representation of the flow cell of the dissolved oxygen sensor, the chlorophyll sensor and the petroleum hydrocarbon sensor in the water of the utility model system;

Fig. 4 is a schematic structural diagram of the COD sensor flow cell of the utility model system;

Fig. 5 is a schematic structural diagram of a system embodiment of the present invention.

Among them, 1 is the upper computer, 2 is the power supply and control module, 3 is the data acquisition module, 4 is the dissolved oxygen sensor, 5 is the COD sensor, 6 is the chlorophyll sensor, 7 is the petroleum hydrocarbon sensor in water, 8 is the defoamer, 9 Injection pump, 10 air compressor, 11 water inlet, 12 drain, 13 throttle valve, 14 one-way valve, 15 communication module, 801 water inlet of defoamer, 802 defoamer 803 is the water outlet of the defoamer, 804 is the overflow of the defoamer, 805 is the shell of the defoamer, 806 is the partition, 16 is the sensor probe of dissolved oxygen, chlorophyll and petroleum hydrocarbons in water, and 17 is dissolved oxygen , chlorophyll and water petroleum hydrocarbon sensor flow cell, 1701 is the air inlet of dissolved oxygen, chlorophyll and water petroleum hydrocarbon sensor flow cell, 1702 is the water inlet of dissolved oxygen, chlorophyll and water petroleum hydrocarbon sensor flow cell, 1703 is Water outlet of dissolved oxygen, chlorophyll and petroleum hydrocarbon sensor flow cell in water, 501 is COD sensor probe, 502 is COD sensor flow cell, 503 is water inlet of COD sensor flow cell, 504 is COD sensor flow cell outlet, 505 is COD The air inlet of the sensor flow cell, 18 is the cabinet, 19 is the antenna, 20 is the electrical box, 21 is the touch screen, 22 is the power socket, 23 is the flow meter, and 24 is the tee.

Detailed ways

As shown in FIG. 1 , it is a structural schematic diagram of an optical online monitoring system for seawater quality. Including control and data acquisition unit, sensor measurement module, air circuit unit and water circuit unit.

The control and data acquisition unit includes a host computer 1, a power supply and control module 2, a data acquisition module 3 and a communication module 15;

The sensor measurement module includes a dissolved oxygen sensor 4, a COD sensor 5, a chlorophyll sensor 6 and a petroleum hydrocarbon sensor 7 in water;

The air compressor 10 and the one-way valve 14 form an air circuit unit;

The waterway unit includes a sampling pump 9 , a water inlet 11 , a throttle valve 13 , a defoamer 8 and a water outlet 12 .

The upper computer 1 controls the sampling pump 9 to feed water through the power supply and control module 2, the water sample to be tested enters the pipeline through the water inlet 11, the water sample to be tested is divided into two through a three-way waterway, and one path is used for testing. The other way discharges excess water samples through the drain port 12, and adds a throttle valve 13 to the water way to control the drainage speed, thereby controlling the sampling speed of the measurement water way. The water sample first enters the dissolved oxygen sensor 4 for the dissolved oxygen test, and the water sample after the test enters the defoamer 8 to perform defoaming treatment on the water sample to eliminate air bubbles in the water sample. The water sample after defoaming treatment enters the COD sensor 5 , chlorophyll sensor 6 and water petroleum hydrocarbon sensor 7 in order to test COD, chlorophyll and water petroleum hydrocarbon respectively, and the water sample after the test is discharged through the drain 12 .

The defoamer 8 includes a defoamer shell 805 , a partition 806 , a defoamer water inlet 801 , a defoamer drain 802 , a defoamer water outlet 803 and a defoamer overflow 804 . The water sample enters the defoamer 8 through the water inlet 801 of the defoamer, and undergoes defoaming treatment through the fixed route flow path of the partition 806. The water sample after the defoaming treatment enters the test waterway through the water outlet 803 of the defoamer for testing. The defoamer 8 reserves a defoamer overflow port 804. When the water flow rate is too fast, excess water samples are directly discharged from the defoamer 8 through the defoamer overflow port 804, and then discharged from the system through the system drain port 12. When the system stops working, part of the water sample will remain in the defoamer 8. At this time, turn on the switch of the defoamer outlet 802 to discharge the water sample from the defoamer 8 and the system through the system outlet 12.

The dissolved oxygen sensor 4, the COD sensor 5, the chlorophyll sensor 6 and the petroleum hydrocarbon sensor 7 in water receive the power supply and the control module 2 instructions for testing, and the data after the test is collected by the data acquisition module 3, and the collected data is finally passed through The upper computer 1 displays or transmits via the communication module 15 .

The communication module 15 is a wireless communication module. Through wireless transmission and remote monitoring technology, users can query, monitor and save marine environmental information in real time through various network terminals. Upper computer 1. The upper computer can use Advantech PPC-3110 industrial computer, the power supply and control module is based on TMS320 chip system design, the data acquisition module uses CR1000 data collector, and the communication module uses USR-GPRS232 communication module.

The air compressor 10 receives the power supply and the command of the control module 2 to regularly feed gas into the COD sensor flow cell 502, dissolved oxygen, chlorophyll and water petroleum hydrocarbon sensor flow cell 17 to clean the sensor light window. A one-way valve 14 is added in the air path to prevent water samples from entering the air compressor 10 .

The dissolved oxygen sensor 4, the COD sensor 5, the chlorophyll sensor 6 and the petroleum hydrocarbon sensor 7 in water are all installed at an angle of 20°C to 85°C to avoid air bubbles attached to the light window of the sensor and impurities in the water sample to settle on the light window.

Example 1

As shown in Figure 5, it is a schematic diagram of an embodiment of the utility model system, including: a dissolved oxygen sensor 4, a COD sensor 5, a chlorophyll sensor 6, a petroleum hydrocarbon sensor 7 in water, a defoamer 8, a sampling pump 9, an air compressor Machine 10, drain port 12, cabinet 18, antenna 19, electrical box 20, touch screen 21, power socket 22, flow meter 23 and tee 24.

The sampling pump 9 can be a peristaltic pump or a submersible pump, and the present embodiment selects a submersible pump; in order to understand the sampling speed of the water sample more intuitively in the waterway, a flow meter 23 is set in the waterway; the upper computer 1 is selected in this embodiment What is above is a touch screen 21; the electrical box 20 includes a power supply and control module 2, a data acquisition module 3 and a communication module 15.

The dissolved oxygen sensor 4 selects the FDO-99 fluorescence dissolved oxygen analyzer; the COD sensor 5 selects the carbo::lyserTM Ⅱ spectral probe of S::can (Yes Energy) in Austria; the chlorophyll sensor 6 selects the microFlu-chl spectral probe of the German TriOS company ; Oil in water hydrocarbon sensor 7 is the US Hach FP360sc oil in water analyzer.

In this embodiment, the dissolved oxygen sensor 4, the COD sensor 5, the chlorophyll sensor 6 and the petroleum hydrocarbon sensor 7 in water are all installed at an angle of 75°C.

Claims (3)

1. An optical online monitoring system for seawater quality, comprising a control and data acquisition unit, a sensor measurement module, an air circuit unit and a water circuit unit; the control and data acquisition unit includes a host computer, a power supply and control module, a data acquisition module and a communication Module; a dissolved oxygen sensor, a COD sensor, a chlorophyll sensor and a petroleum hydrocarbon sensor in water form a sensor measurement module; it is characterized in that: The air circuit unit includes an air compressor and a one-way valve; The waterway unit includes a sampling pump, a water inlet, a throttle valve, a defoamer and a drain; The upper computer is electrically connected to the power supply and control module, and the power supply and control module is connected to the dissolved oxygen sensor, COD sensor, chlorophyll sensor, petroleum hydrocarbon sensor in water, sampling pump, and air compressor. The data acquisition module is connected to the dissolved oxygen sensor, COD Sensors, chlorophyll sensors, petroleum hydrocarbon sensors in water, and upper computer are electrically connected to communication modules; The sampling pump is connected to the water inlet, the water inlet is a three-way type, and one road is connected to the throttle valve and the system drain in sequence; the other road is connected to the defoamer; the water outlet of the defoamer is connected to the COD sensor, chlorophyll The sensor and the petroleum hydrocarbon sensor in water are connected sequentially; the overflow port of the defoamer is connected with the system drain port; The air compressor is respectively connected to the light window of the flow cell of the COD sensor flow cell, the dissolved oxygen sensor, the chlorophyll sensor and the petroleum hydrocarbon sensor in water through a one-way valve; The dissolved oxygen sensor, COD sensor, chlorophyll sensor and petroleum hydrocarbon sensor in water are all installed at an angle of 20°C to 85°C. 2. A kind of sea water quality optical on-line monitoring system according to claim 1, characterized in that: the defoamer comprises a defoamer shell, a partition, a defoamer water inlet, a defoamer outlet, a defoamer The water outlet of the defoamer and the overflow of the defoamer; the water sample enters the defoamer from the water inlet of the defoamer, and undergoes defoaming treatment through the fixed route flow path of the partition, and the water sample after defoaming treatment enters the test through the outlet of the defoamer The waterway is tested; the defoamer overflow port is connected with the system drain port; the defoamer drain port is also connected with the system drain port through a switch. 3. The optical on-line monitoring system for sea water quality according to claim 1, characterized in that: the sampling pump is a peristaltic pump or a submersible pump.