CN203629617U - Wireless hydrologic monitoring device of nuclear power plant - Google Patents

Abstract

The utility model discloses a wireless hydrological monitoring device for a nuclear power plant, which is characterized in that the device comprises: an offshore buoy monitoring unit, which is used to carry a first hydrological measurement sensor through the buoy to measure hydrological data in the offshore area; a fixed station on the coast The monitoring unit is used to measure the hydrological data in the coastal field through the second hydrological measurement sensor arranged in the shore station house; the data collection platform is used to collect the hydrological data measured by the offshore buoy monitoring unit and the fixed station monitoring on the coast The hydrological data measured by the unit; the data transmission station transmission unit, including at least one wireless data transmission station, is used to send the hydrological data collected by the data acquisition platform to the central station data center; the central station data center is used to receive, store and analyze data The hydrological data transmitted by the transmission unit of the radio station. The utility model provides a complete hydrological monitoring solution for the nuclear power plant. Moreover, the reliability of data transmission is improved.

Description

A wireless hydrological monitoring device for a nuclear power plant

technical field

The utility model relates to the field of hydrological monitoring, in particular to a hydrological monitoring device based on a digital transmission station and applied to nuclear power plants.

Background technique

Hydrological data is one of the important data sources for emergency command and decision-making in nuclear power plants. In order to make timely and accurate emergency command decisions, nuclear power plants need to monitor hydrology. At present, my country attaches great importance to hydrological monitoring, but the technical means of monitoring are still relatively backward. Many monitoring areas such as sea areas and remote lakes and rivers are still using artificial methods to observe hydrological data regularly. Moreover, the geographical environment of hydrological monitoring is remote, the monitoring locations are relatively scattered, and the area covers a wide range, mostly in oceans, lakes, rivers, etc. It is difficult to transmit information by wire, and it will increase the cost. Therefore, using wireless transmission is the best method. s Choice. Currently used wireless technologies include GPRS, satellite communications, ZigBee, etc. However, under extreme environmental conditions (such as earthquakes, tsunamis, floods, etc.), the above-mentioned communication network is basically in a state of paralysis, and the collected data cannot be transmitted to the emergency command center. In addition, the cost of satellite communication is high, and GPRS depends on the operator.

In addition, the types of hydrological data obtained by current hydrological monitoring cannot fully meet the needs of nuclear power plants for hydrological data, such as the demand for nuclear radiation in water.

To sum up, there is still no complete and reasonable hydrological monitoring scheme in the field of nuclear power plants.

Contents of the invention

The purpose of this utility model is to provide a wireless hydrological monitoring device for a nuclear power plant to solve the demand for hydrological monitoring in the field of existing nuclear power plants.

Based on the above purpose, the embodiment of the utility model provides a wireless hydrological monitoring device of a nuclear power plant, the device includes:

The offshore buoy monitoring unit is used to carry the first hydrographic measurement sensor through the buoy to measure hydrological data in the offshore area;

The coast fixed station monitoring unit is used to measure the hydrological data in the coastal area through the second hydrological measurement sensor arranged in the shore station house;

A data collection platform, configured to collect the hydrological data measured by the offshore buoy monitoring unit and the hydrological data measured by the coastal fixed station monitoring unit;

The data transmission station transmission unit includes at least one pair of wireless data transmission stations, which are used to send the hydrological data collected by the data collection platform to the data center of the central station;

The central station data center is used to receive, store and analyze the hydrological data transmitted by the transmission unit of the digital transmission station.

Preferably, the device also includes:

The nuclear power plant emergency command and decision-making system is used to analyze the hydrological data sent by the data center of the central station in real time, and generate relevant instructions according to the analysis results.

Preferably, when the specified data collection time is reached, the data collection platform sends a data collection command to the offshore buoy monitoring unit and the coastal fixed station monitoring unit;

The offshore buoy monitoring unit and the coastal fixed station monitoring unit start a data collection process according to the data collection command.

Preferably, the first hydrological measurement sensor includes at least a temperature sensor, a salinity sensor, a dissolved oxygen sensor, a wave sensor, an ocean current sensor, a nuclide sensor in water, and a sand content sensor; the second hydrological measurement sensor includes at least a tide level sensor , sand concentration sensor, temperature sensor and salinity sensor.

Preferably, the data transmission station transmission unit includes a wireless data transmission station host and at least one wireless data transmission station slave;

The data transmission station slave is used to obtain the hydrological data collected by the data collection platform and send it to the wireless data transmission station host;

The wireless data transmission station master is used to send the hydrological data received from the data transmission station slave to the central station data center.

Preferably, the wireless data transmission station slave is used to send the hydrological data to the wireless data transmission station master through multi-stage forwarding when an obstacle is encountered.

Preferably, the data collection platform is a data collector using an ARM embedded system, and WINCE software is run on the data collector.

Preferably, the data acquisition platform communicates with the first hydrological measurement sensor and the second hydrological measurement sensor through RS232 or RS485, and communicates with the digital transmission station transmission unit through RS232.

Preferably, the data collection platform is also used to store the collected hydrological data locally;

and / or;

The data collection platform is also used for sending an alarm signal when it is judged that the hydrological data exceeds a preset threshold.

Preferably, the central station data center includes:

A data acquisition workstation, configured to receive the hydrological data sent by the transmission unit of the digital transmission station, store the hydrological data in a local database and send the hydrological data to a network server;

A network server, configured to store the received hydrological data in real time and send the hydrological data;

The network server is also used to generate corresponding data reports and statistical charts according to the hydrological data;

The data monitoring workstation is used to display the hydrological data in real time.

The beneficial effects of the utility model are:

The utility model can measure the hydrology of the offshore and the coast to obtain hydrological data by setting the offshore buoy monitoring unit and the coastal fixed station monitoring unit, and then obtain the above hydrological data through the data acquisition platform, and transmit the hydrological data through the wireless data transmission station Send it to the data center of the central station for analysis and storage in the data center of the central station. Provide data support for nuclear power plant staff to monitor the site situation in time, accurately judge the current status, and provide data support for maintenance or emergency repair. The utility model provides a complete hydrological monitoring solution for the nuclear power plant. Moreover, the utility model utilizes wireless data transmission stations to transmit data, which can cope with extreme environmental conditions, and users can self-organize networks without relying on operators. the

Description of drawings

Fig. 1 is a structural diagram of the utility model device;

Fig. 2 is the utility model data acquisition platform communication diagram;

Fig. 3A is a communication schematic diagram of the data transmission station transmission unit of the utility model when there is no obstacle;

Fig. 3B is a communication schematic diagram of the transmission unit of the digital transmission station when there is an obstacle in the present invention.

Detailed ways

The technical solutions in the embodiments of the present invention will be clearly and completely described below in conjunction with the accompanying drawings in the embodiments of the present invention. Obviously, the described embodiments are only part of the embodiments of the present invention, not all of them. example. Based on the embodiments of the present utility model, all other embodiments obtained by persons of ordinary skill in the art without making creative efforts belong to the scope of protection of the present utility model.

Embodiment 1 of the utility model provides a wireless hydrological monitoring device for a nuclear power plant. Referring to FIG. 1 , the device includes: offshore buoy monitoring unit 11 , coastal fixed station monitoring unit 12 , data collection platform 13 , data transmission station transmission unit 14 and central station data center 15 . in:

The offshore buoy monitoring unit 11 is configured to measure hydrological data in the offshore area by carrying the first hydrological measurement sensor on the buoy. Based on the special needs of nuclear power plants, nuclides in water need to be measured. The hydrological data in the utility model usually include parameters such as temperature, salinity, ocean waves, ocean currents, dissolved oxygen, and nuclides in water. Correspondingly, the first hydrographic measurement sensor generally includes a temperature sensor, a salinity sensor, a sea wave sensor, a sea current sensor, a dissolved oxygen sensor, and a nuclide sensor in water (a nuclide monitor in water). Certainly also can measure a plurality of parameters with a kind of equipment in the utility model, as multi-parameter water quality meter, Doppler flow meter, wherein Doppler flow meter can measure flow velocity and water temperature at the same time, be especially suitable for silt content height, aquatic plants Debris-rich waters.

In the utility model, the buoy material can be selected from a low surface energy polymer material, which has the characteristics of corrosion resistance, collision resistance, light weight, long life and is not easy to be attached by organisms, and is suitable for use in waters.

In the embodiment of the utility model, the offshore buoy monitoring unit 11 is equipped with a GPS positioning function. Once the buoy drifts away from the preset range, it will be positioned by the GPS immediately, and immediately alarm the mobile phone according to the program setting and report the longitude and latitude of the buoy. In the present invention, the first hydrological measurement sensor further includes a memory for storing the measured hydrological data in real time, so as to ensure that the measured hydrological data will not be lost in the event of a failure. The memory capacity of the memory shall not be less than 15,000 measurement data or not less than 6 months of storage.

In order to ensure the confidentiality and reliability of data transmission, the offshore buoy monitoring unit 11 of the utility model can be equipped with multiple data transmission functions, such as the coexistence of wired and wireless transmission modes, or the coexistence of multiple wired or multiple wireless modes.

Based on the particularity of water area measurement, the offshore buoy monitoring unit 11 of the present invention also includes a solar power supply device. It can ensure the normal power supply to the buoy in 30 consecutive days of cloudy and rainy days (without the sun), without affecting the normal operation of the hydrographic measuring instruments. The solar panels it uses have the characteristics of high energy conversion efficiency, corrosion resistance, wind and wave resistance, impact and scratch resistance, and long service life.

In addition, the offshore buoy monitoring unit 11 in the utility model also includes an automatic alarm device, which will automatically alarm when the hydrological measurement data exceeds the warning line and/or the battery voltage is too high. In the utility model, it can be set to alarm to a programmed mobile phone. .

Further, the offshore buoy monitoring unit 11 in the present invention also has functions such as data statistics and curve query.

The offshore buoy monitoring unit 11 in the utility model can monitor continuously on-line for a long period of time, so that users can understand real-time data and analyze and predict hydrological conditions. The maintenance period is long, and the maintenance period is generally not less than 30 days and does not discharge pollutants to the surrounding environment to avoid secondary pollution of the environment.

The coastal fixed station monitoring unit 12 is used to measure hydrological data in the coastal area through the second hydrological measurement sensor arranged in the shore station house.

In the specific embodiment of the utility model, the coastal fixed station monitoring unit 12 is composed of a shore station house, a power distribution system, a second hydrological measurement sensor and an uninterruptible power supply (UPS).

Among them, the hydrological data measured in the coastal areas mainly include temperature, salinity, sediment concentration, tide level, etc., and the corresponding second hydrological measurement sensors include at least a temperature sensor, a salinity sensor, a sand concentration sensor and a tide level sensor.

In the embodiment of the utility model, the second hydrological measurement sensor further includes a memory for storing the measured hydrological data, so as to ensure that the measured hydrological data will not be lost in the event of failure. The instrument memory capacity of the controller shall not be less than 15,000 measurement data or not less than 6 months storage capacity.

The coastal fixed station monitoring unit 12 communicates with the outside world through wireless data transmission. In order to ensure the confidentiality and reliability of data transmission, the coastal fixed station monitoring unit 12 can be configured with multiple data transmission functions, such as wireless and wired data transmission.

In the utility model, the monitoring unit 12 of the fixed station on the coast also includes an automatic alarm device, which is used to automatically alarm when the hydrological data exceeds the warning line, such as automatically alarming a programmed mobile phone.

Due to the adoption of an uninterruptible power supply (UPS), the monitoring unit 12 of the fixed station on the coast can continue to operate for 72 hours in the event of a power failure.

In the utility model, the monitoring unit 12 of the fixed station on the coast can monitor on-line for a long time, so that users can understand real-time data and analyze and predict hydrological conditions.

The data collection platform 13 is used to collect the hydrological data measured by the offshore buoy monitoring unit and the hydrological data measured by the coastal fixed station monitoring unit.

In the utility model, the data collection platform 13 preferably adopts an ARM embedded system, and runs a data collector of WINCE software. The data collector is connected with each sensor in the offshore buoy monitoring unit 11 and the coastal fixed station monitoring unit 12 through RS232 or RS485, and sends data to the data transmission station transmission unit 14 through RS232. Figure 2 of the utility model is a schematic diagram of data transmission between the data collector, the sensor and the transmission unit of the digital transmission station.

The data acquisition platform 13 in the utility model also includes a memory for storing the collected hydrological data locally, or the data acquisition platform further includes an alarm device for sending an alarm signal when the hydrological data exceeds a preset threshold. The memory capacity of the data acquisition platform shall not be less than 8,000 measurement data or not less than 3 months of storage. `` ``

The data transmission station transmission unit 14 includes at least one pair of wireless data transmission stations for sending the hydrological data collected by the data collection platform to the data center 15 of the central station.

As shown in FIG. 1 , in the embodiment of the present invention, the data transmission station transmission unit 14 includes a wireless data transmission station master 141 and at least one wireless data transmission station slave 142 .

Wherein, the data transmission station slave 142 is used to obtain the hydrological data collected by the data acquisition platform 13 and send it to the wireless data transmission station host 141;

The wireless data transmission host 141 is used to send the hydrological data received from the digital transmission slave 142 to the data center 15 of the central station.

The utility model adopts the wireless data transmission station with relay forwarding function to transmit data, and each wireless data transmission station itself is a router. When there is an obstacle, the wireless data transmission station will find the nearest station through multi-stage forwarding, and finally bypass the obstacle to transmit the data to the emergency command center. Figures 3A and 3B of the present invention respectively show the communication process of the transmission unit of the digital transmission station when there is no obstacle and when there is an obstacle.

The central station data center 15 is used to receive, store and analyze the hydrological data transmitted by the transmission unit 14 of the digital transmission station.

In the embodiment of the utility model, the central station data center 15 is composed of a data collection workstation, a network server, a data monitoring workstation and network communication equipment. The following is a detailed introduction to the data acquisition workstation, network server, data monitoring workstation and network communication equipment:

Data Acquisition Workstation

In order to meet the requirements of working under extreme conditions such as earthquakes, the data acquisition workstation adopts a high-performance industrial computer to obtain relevant monitored hydrological data from the offshore buoy monitoring unit 11 and the coastal fixed station monitoring unit 12 through the wireless data transmission station. After processing, it is stored in the local database, and the data is transmitted to the network server database.

Network Server

The main functions of the web server in the network are:

1. Domain controller: A combination of computers that controls whether computers in the network can join, including a database composed of information such as accounts, passwords, and computers belonging to this domain. When a computer is connected to the network, the domain controller must first identify whether the computer belongs to the domain, whether the login account used by the user exists, and whether the password is correct. Manage computers in the network;

2. Database server: store real-time monitoring data. In the preferred implementation, the corresponding environmental monitoring data and meteorological data are provided to the emergency command and decision-making system of the nuclear power plant.

3. File sharing server: Generate various data reports and statistical charts according to the data in the database server, and convert them into file formats that are easy to handle by general office software for sharing within the network.

The network server adopts a high-performance dedicated server and is equipped with a multi-hard disk backup system to ensure the reliability of monitoring data.

Data Monitoring Workstation

The data monitoring workstation adopts a reinforced portable computer, which is stored in a special case at ordinary times. When necessary, it can be connected to the data center network of the central station and used as a data terminal to display real-time hydrological monitoring data on a large screen.

network communication equipment

The computers and devices in the central station data center form a data network through switches.

In a preferred embodiment of the present invention, the above-mentioned hydrological monitoring device further includes: a nuclear power plant emergency command and decision-making system, which is used to analyze the hydrological data sent by the data center of the central station in real time, and generate relevant instructions according to the analysis results. Specifically, the computers and equipment in the data center of the central station realize data exchange with the emergency command and decision-making system (KCC) of the nuclear power plant through a data network constructed by switches through routers.

The communication in the utility model is two-way. The hydrological data measured by the offshore buoy monitoring unit 11 and the coastal fixed station monitoring unit 12 can be finally transmitted to the central station data center through the data acquisition platform 13 and the digital transmission station transmission unit 14, and then transmitted to the nuclear power plant through the central station data center Emergency command and decision-making system, and the relevant instructions and data of the nuclear power plant emergency command and decision-making system and the central station data center can also be transmitted to the offshore buoy monitoring unit 11 and the coastal fixed station monitoring through the digital transmission station transmission unit 14 and the data acquisition platform 13 Unit 12.

In the specific embodiment of the utility model, when the specified data collection time is reached, the data collection platform can send data collection commands to the offshore buoy monitoring unit and the coastal fixed station monitoring unit, so that the offshore buoy monitoring unit and the coastal fixed station monitoring unit Start the data collection process according to the data collection command.

The utility model can measure the hydrology of the offshore and the coast to obtain hydrological data by setting the offshore buoy monitoring unit and the coastal fixed station monitoring unit, and then obtain the above hydrological data through the data acquisition platform, and transmit the hydrological data through the wireless data transmission station Send it to the data center of the central station for analysis and storage in the data center of the central station. Provide data support for nuclear power plant staff to monitor the site situation in time, accurately judge the current status, and provide data support for maintenance or emergency repair. The utility model provides a complete hydrological monitoring solution for the nuclear power plant. Moreover, the utility model utilizes wireless data transmission stations to transmit data, which can cope with extreme environmental conditions, and users can self-organize networks without relying on operators. the

The above specific embodiments have further described the purpose, technical solutions and beneficial effects of the utility model in detail. It should be noted that the above is only a specific embodiment of the utility model, and those skilled in the art can understand the utility model. Various changes and modifications can be made without departing from the spirit and scope of the utility model. In this way, if these modifications and variations of the utility model fall within the scope of the claims of the utility model and equivalent technologies thereof, the utility model is also intended to include these modifications and variations.

Claims (10)

1. a wireless hydrologic monitoring device for nuclear power plant, is characterized in that, described device comprises:

Coastal waters buoy monitoring means, for carry the first hydrographic survey sensor by buoy, measures the hydrographic data in field, coastal waters;

Seashore limit fixed station monitoring means, for by being arranged on the second hydrographic survey sensor in the station of bank, measures the hydrographic data in field, seashore limit;

Data acquisition platform, for gathering the hydrographic data of described coastal waters buoy monitoring means measurement and the hydrographic data that described seashore limit fixed station monitoring means is measured;

Data radio station transmission unit, comprises at least one pair of wireless digital broadcasting station, for the hydrographic data of data acquisition platform collection is sent to central station data center;

Central station data center, for receiving, store and analyze the described hydrographic data of described data radio station transmission unit transmission.

2. hydrologic monitoring device as claimed in claim 1, is characterized in that, described device also comprises:

Nuclear power plant's Emergency command decision-making system, carries out real-time analysis for the described hydrographic data that described central station data center is sent, and generates dependent instruction according to analysis result.

3. hydrologic monitoring device as claimed in claim 1, is characterized in that, in the time arriving the image data time of specifying, described data acquisition platform sends data acquisition command to described coastal waters buoy monitoring means and described seashore limit fixed station monitoring means;

Described coastal waters buoy monitoring means and described seashore limit fixed station monitoring means are according to described data acquisition command turn-on data gatherer process.

4. hydrologic monitoring device as claimed in claim 1, it is characterized in that, described the first hydrographic survey sensor at least comprises temperature sensor, salinity sensor, dissolved oxygen sensor, wave sensor, ocean current sensor, water Radionuclide sensor and silt content sensor; Described the second hydrographic survey sensor at least comprises tide level sensor, silt content sensor, temperature sensor and salinity sensor.

5. hydrologic monitoring device as claimed in claim 1, is characterized in that, described data radio station transmission unit comprises a wireless digital broadcasting station main frame and at least one wireless digital broadcasting station slave;

Described data radio station slave, for obtaining the hydrographic data of described data acquisition platform collection and being sent to described wireless digital broadcasting station main frame;

Described wireless digital broadcasting station main frame, for being sent to the described hydrographic data receiving from described data radio station slave described central station data center.

6. hydrologic monitoring device as claimed in claim 5, is characterized in that, described wireless digital broadcasting station slave, in the time running into barrier, is sent to described wireless digital broadcasting station main frame by multi-level forwarding by described hydrographic data.

7. hydrologic monitoring device as claimed in claim 1, is characterized in that, described data acquisition platform is the data acquisition unit that adopts ARM embedded system, moves WINCE software on described data acquisition unit.

8. hydrologic monitoring device as claimed in claim 1, it is characterized in that, described data acquisition platform passes through RS232 or RS485 and described the first hydrographic survey sensor and described the second hydrographic survey sensor communication, and by RS232 and the communication of described data radio station transmission unit.

9. hydrologic monitoring device as claimed in claim 1, is characterized in that, described data acquisition platform also comprises storer, for the described hydrographic data gathering is stored in this locality;

And/or;

Described data acquisition platform also comprises alarm, for send alerting signal in the time that described hydrographic data exceedes predetermined threshold value.

10. hydrologic monitoring device as claimed in claim 1, is characterized in that, described central station data center comprises:

Data collection task station, the described hydrographic data sending for receiving described data radio station transmission unit, is stored in described hydrographic data local data base and described hydrographic data is sent to the webserver;

The webserver, the described hydrographic data receiving for real-time storage, and described hydrographic data is sent;

The described webserver, also for generating corresponding data sheet and statistical graph according to described hydrographic data;

Data monitoring workstation, for showing in real time described hydrographic data.

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