CN202661108U - On-line ocean distribution type thermohaline deep-flowing dynamic real-time monitoring system - Google Patents
On-line ocean distribution type thermohaline deep-flowing dynamic real-time monitoring system Download PDFInfo
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- CN202661108U CN202661108U CN 201220300378 CN201220300378U CN202661108U CN 202661108 U CN202661108 U CN 202661108U CN 201220300378 CN201220300378 CN 201220300378 CN 201220300378 U CN201220300378 U CN 201220300378U CN 202661108 U CN202661108 U CN 202661108U
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Abstract
Provided is an on-line ocean distribution type thermohaline deep-flowing dynamic real-time monitoring system. A computer is connected with a data exchanger which is respectively and sequentially connected with a temperature data collecting and controlling device, a salinity data collecting and controlling device, a depth data collecting and controlling device, a flowing velocity data collecting and controlling device and a flowing direction data collecting and controlling device, and the temperature data collecting and controlling device. The salinity data collecting and controlling device, the depth data collecting and controlling device, the flowing velocity data collecting and controlling device and the flowing direction data collecting and controlling device are respectively connected with bus repeaters of the temperature, salinity, depth, flowing velocity and flowing direction, and the temperature, salinity, depth, flowing velocity and flowing direction bus repeaters are respectively connected with a plurality of different monitoring program sensors with the same internet protocol (IP) addresses on the connection line of the same monitoring program. The on-line ocean distribution type thermohaline deep-flowing dynamic real-time monitoring system avoids corrosion to the sensors caused by seawater, reduces the manufacture cost and simultaneously improves the detection accuracy. Data signals can be transmitted into on-land monitoring stations in dozens of kilometers, and the requirements for ocean hydrogeology detection can be met.
Description
Technical field
The utility model belongs to the micro sensing technical field, specifically relates to the online Real-Time Ocean thermohaline of a kind of online Real-Time Ocean and deeply flows monitoring system.
Background technology
Be to adopt manually to detect to the monitoring method general of ocean temperature, salinity, the degree of depth, flow velocity and the flow direction at present, consuming time, expend, consume manpower and monitoring accuracy is lower, near the tidal station also need having simultaneously carries out the tidal level correction.The 2nd, adopt wired ocean water dynamic environment dynamic monitoring system, its price is high, be difficult to extensively layout and the long-term cloth of electrical method sensor is placed on and is vulnerable to marine corrosion in the seawater and causes permanent failure.
The utility model content:
The utility model provides the online Real-Time Ocean thermohaline of a kind of online Real-Time Ocean deeply to flow monitoring system.Not only overcome the corrosion of seawater to sensor, reduced cost, improved simultaneously accuracy of detection, its data-signal can transmit in tens kilometers the monitoring station, land, reaches the requirement that ocean water conservancy project ring geology detects.
The utility model is achieved in that
The dark flowable state real-time monitoring system of the distributed thermohaline in a kind of online ocean is characterized in that: computing machine connection data interchanger, data exchange unit connect respectively the separately data acquisition and control device of temperature, salinity, the degree of depth, flow velocity and the flow direction; Temperature, salinity, the degree of depth, flow velocity and the flow direction are connected data acquisition and control device separately and are connected respectively the separately bus repeaters of temperature, salinity, the degree of depth, flow velocity and the flow direction; Temperature, salinity, the degree of depth, flow velocity and the flow direction be connected bus repeaters separately connect a plurality of identical temperature sensors with the IP address at the connecting line of same monitoring project respectively, with the temperature sensor of IP address, with the salinity sensor of IP address, with the liquid level sensor of IP address, with the flow sensor of IP address with the temperature sensor of IP address.
The utility model characteristics and advantage:
This online online Real-Time Ocean thermohaline of Real-Time Ocean flows monitoring system deeply.Not only overcome the corrosion of seawater to sensor, reduced cost, improved simultaneously accuracy of detection, its data-signal can transmit in tens kilometers the monitoring station, land, reaches the requirement that ocean water conservancy project ring geology detects.
Simultaneously, sensor signal transmission line and the supply lines of the dynamic monitoring of ocean temperature, salinity, the degree of depth, flow velocity and the flow direction needed 16 lines to each sea layer, then need nearly hundred lines if (such as 5 layers) are measured in layering.So thick diameter cable is difficult for doing preservative treatment, and the marine corrosion that lays for a long time in the ocean will cause permanent failure.This project utility model then is the sensor that adopts with the IP address, with single bus as data line, not only realize easily the corrosion-resistant treatments of transducing signal line, reduced cost, simultaneously can freely carry additionally the sensors such as ocean temperature, salinity, the degree of depth, flow velocity and the flow direction at transfer bus by ocean water dynamic environment monitoring requirements, improved overall accuracy of detection, its data-signal can transmit in tens kilometers the monitoring station, land, reaches the actual requirement that the ocean water dynamic environment is dynamically carried out accurate Real-Time Monitoring
Description of drawings
Fig. 1 is that the online Real-Time Ocean thermohaline of online Real-Time Ocean flows the monitoring system block diagram deeply.Among the figure: (1-1) be the temperature sensor with the IP address; (1-2) be the salinity sensor with the IP address; (1-3) be the liquid level sensor with the IP address; (1-4) be the flow sensor with the IP address; (1-5) for being the temperature sensor with the IP address, (2-1) be the temperature sensor with the IP address; (2-2) be the salinity sensor with the IP address; (2-3) be the liquid level sensor with the IP address; (2-4) be the flow sensor with the IP address; (2-5) be the temperature sensor with the IP address, (n-1) be the temperature sensor with the IP address; (n-2) be the salinity sensor with the IP address; (n-3) be the liquid level sensor with the IP address; (n-4) be the flow sensor with the IP address; (n-5) for being the temperature sensor with the IP address.(5) be the bus of temperature, salinity, the degree of depth, flow velocity and the flow direction independently separately; (6), (7), (8), (9), (10) are the separately bus repeaters of temperature, salinity, the degree of depth, flow velocity and the flow direction; (11), (12), (13), (14), (15) are that separately data acquisition and control device, (16) of temperature, salinity, the degree of depth, flow velocity and the flow direction are data exchange unit; (17) be computing machine.
Embodiment
The dark flowable state real-time monitoring system of the distributed thermohaline in a kind of online ocean, computing machine connection data interchanger, data exchange unit connect respectively the separately data acquisition and control device of temperature, salinity, the degree of depth, flow velocity and the flow direction; Temperature, salinity, the degree of depth, flow velocity and the flow direction are connected data acquisition and control device separately and are connected respectively the separately bus repeaters of temperature, salinity, the degree of depth, flow velocity and the flow direction; Temperature, salinity, the degree of depth, flow velocity and the flow direction be connected bus repeaters separately connect a plurality of identical temperature sensors with the IP address at the connecting line of same monitoring project respectively, with the temperature sensor of IP address, with the salinity sensor of IP address, with the liquid level sensor of IP address, with the flow sensor of IP address with the temperature sensor of IP address.
Above-mentioned these sensors all have unique number itself, therefore can carry additionally several sensors in single bus, (1-1), (2-1)---and (n-1) in parallel on a transmission lines; (1-2), (2-2)---(n-2) in parallel on a transmission lines; (1-3), (2-3)---(n-3) in parallel on a transmission lines; (1-4), (2-4)---(n-4) in parallel on a transmission lines; (1-5), (2-5)---(n-5) in parallel on a transmission lines; Measured ocean layer temperature, salinity, the degree of depth, flow velocity and flow directional detection data of transmission sensor independently on the bus of temperature, salinity, the degree of depth, flow velocity and the flow direction separately.Independently the bus of temperature, salinity, the degree of depth, flow velocity and the flow direction (5) is connected to respectively separately bus repeaters (6), (7), (8), (9), (10) of temperature, salinity, the degree of depth, flow velocity and the flow direction separately; Temperature, salinity, the degree of depth, flow velocity and the flow direction are connected separately bus repeaters (6), (7), (8), (9), (10) and are connected respectively separately data acquisition and control device (11), (12), (13), (14), (15) of temperature, salinity, the degree of depth, flow velocity and the flow direction; The separately data acquisition and control device (11) of temperature, salinity, the degree of depth, flow velocity and the flow direction, (12), (13), (14), (15) connection data interchanger (16); Data exchange unit (16) is connected with computing machine (17).
The utility model is like this work:
These temperature, salinity, the degree of depth, flow velocity and flow direction sensor all have the unique number of itself, therefore can carry additionally several sensors of the same type in single bus, under the control of computing machine (17), temperature, salinity, the degree of depth, the separately data acquisition and control device (11) of flow velocity and the flow direction, (12), (13), (14), (15) send measuring command, start every sea layer temperature, salinity, the degree of depth, flow velocity and flow direction sensor work, every sea layer temperature, salinity, the degree of depth, flow velocity and flow direction sensor add that with data measured IP address separately passes through temperature as complete message, salinity, the degree of depth, the separately independent bus line transponder (6) of flow velocity and the flow direction, (7), (8), (9), (10) reach temperature, salinity, the degree of depth, the separately data acquisition and control device (11) independently of flow velocity and the flow direction, (12), (13), (14), (15); These data channel reach computing machine (17) demonstration, data processing and database through data exchange unit (16).
The operation using method of utility model
The below illustrates the operation use procedure of this utility model, for example do not affect the further protection of patent.
These temperature, salinity, the degree of depth, flow velocity and flow direction sensor all have the unique number of itself, therefore can carry additionally several sensors of the same type in single bus, under the control of computing machine (17), temperature, salinity, the degree of depth, the separately data acquisition and control device (11) of flow velocity and the flow direction, (12), (13), (14), (15) send measuring command, start every sea layer temperature, salinity, the degree of depth, flow velocity and flow direction sensor work, every sea layer temperature, salinity, the degree of depth, flow velocity and flow direction sensor add that with data measured IP address separately passes through temperature as complete message, salinity, the degree of depth, the separately independent bus line transponder (6) of flow velocity and the flow direction, (7), (8), (9), (10) reach temperature, salinity, the degree of depth, the separately data acquisition and control device (11) independently of flow velocity and the flow direction, (12), (13), (14), (15); These data channel reach computing machine (17) demonstration, data processing and database through data exchange unit (16).
Claims (1)
1. dark flowable state real-time monitoring system of the distributed thermohaline in online ocean, it is characterized in that: computing machine connection data interchanger, data exchange unit connect respectively the separately data acquisition and control device of temperature, salinity, the degree of depth, flow velocity and the flow direction; Temperature, salinity, the degree of depth, flow velocity and the flow direction are connected data acquisition and control device separately and are connected respectively the separately bus repeaters of temperature, salinity, the degree of depth, flow velocity and the flow direction; Temperature, salinity, the degree of depth, flow velocity and the flow direction be connected bus repeaters separately connect a plurality of identical temperature sensors with the IP address at the connecting line of same monitoring project respectively, with the temperature sensor of IP address, with the salinity sensor of IP address, with the liquid level sensor of IP address, with the flow sensor of IP address with the temperature sensor of IP address.
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN102721440A (en) * | 2012-06-26 | 2012-10-10 | 中国地质调查局水文地质环境地质调查中心 | Online marine distributed temperature, salinity and depth flow dynamic real-time monitoring system |
CN111238554A (en) * | 2020-03-30 | 2020-06-05 | 南京信息工程大学 | Multi-parameter sensing bin for ocean, monitoring method and manufacturing method of sensing bin |
-
2012
- 2012-06-26 CN CN 201220300378 patent/CN202661108U/en not_active Expired - Fee Related
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN102721440A (en) * | 2012-06-26 | 2012-10-10 | 中国地质调查局水文地质环境地质调查中心 | Online marine distributed temperature, salinity and depth flow dynamic real-time monitoring system |
CN111238554A (en) * | 2020-03-30 | 2020-06-05 | 南京信息工程大学 | Multi-parameter sensing bin for ocean, monitoring method and manufacturing method of sensing bin |
CN111238554B (en) * | 2020-03-30 | 2022-02-11 | 南京信息工程大学 | Multi-parameter sensing bin for ocean, monitoring method and manufacturing method of sensing bin |
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CF01 | Termination of patent right due to non-payment of annual fee |
Granted publication date: 20130109 Termination date: 20160626 |
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CF01 | Termination of patent right due to non-payment of annual fee |