CN113222333A - Radioactive source management system - Google Patents

Abstract

The invention provides a radiation source management system, comprising: the system comprises a login unit, a radioactive source node monitoring unit, a log unit, a permission management unit and a communication unit. The login unit is used for logging in the system; the radioactive source node monitoring unit comprises radioactive source node early warning and radioactive source node checking; the log unit includes: system operation logs, alarm logs and shift log; the authority management unit comprises personnel setting and account setting; the communication unit comprises TCP/IP communication and GSM network communication; the beneficial effects provided by the invention are as follows: the complete set of complete radioactive source management system is provided, humanization and intellectualization are realized, and the state information of temperature and humidity, displacement early warning and the like of any monitoring node can be checked in real time.

Description

Radioactive source management system

Technical Field

The present invention relates to the field of computer systems, and more particularly, to a radiation source management system.

Background

The radioactive source is an entity or a substance which is made of radioactive substances and can generate irradiation or radiation, has wide application in various fields such as national defense, medical treatment, scientific research, industry, agriculture, energy and the like, and plays an important role in maintaining the safety of national defense and promoting the development of national economy and society. However, once the radioactive source is out of control, the radioactive source can cause radioactive pollution to the environment, and social panic is caused, so that the intensive monitoring and management of the radioactive source are very important.

The radiation source safety and protection management method widely adopted at present mainly utilizes radiation detection technology, video monitoring, GIS geographic information technology and GPS global positioning technology to realize real-time monitoring of the state position of the radiation source, and then combines sensor detection technology, communication technology and computer control technology to establish a radiation source dose monitoring and runaway alarm platform, thereby providing a modern digital solution for radiation source monitoring for supervision departments and related units. However, technologies such as radiation detection, video monitoring, GIS, GPS and traditional communication have large power consumption, so that manual regular maintenance and frequent battery replacement are required, the labor cost and the battery power supply cost are increased invisibly, and the risk that maintenance personnel contact the radiation source is increased. For portable radiation sources with smaller volumes, the use of batteries also makes the radiation source supervision system too bulky to install.

Disclosure of Invention

Aiming at the technical problems, in view of the advantages that the sensing equipment for passive Wi-Fi communication has low power consumption, does not need a battery, is small in size, low in production cost, fully sealed, free of manual maintenance, easy to deploy in a large amount and the like, the invention provides a radioactive source management system based on the passive Wi-Fi Internet of things technology.

The invention provides a radioactive source management system, which comprises: the system comprises a login unit, a radioactive source node monitoring unit, a log unit, a permission management unit and a communication unit. The login unit is used for logging in the system; the radioactive source node monitoring unit comprises radioactive source node early warning and radioactive source node checking; the log unit includes: system operation logs, alarm logs and shift log; the authority management unit comprises personnel setting and account setting; the communication unit includes TCP/IP communication and GSM network communication.

Further, the login unit is used for inputting an account and a password, and judging whether the login authority is provided by verifying an MD5 value corresponding to the account and the password; if the MD5 values corresponding to the account number and the password are consistent with the MD5 value preset to the SQL database, the system is successfully accessed through verification, otherwise, the verification fails.

Further, the radioactive source node early warning comprises: temperature and humidity abnormity early warning, radioactive source abnormal vibration early warning and radioactive source out-of-control alarm.

Furthermore, the radioactive source nodes are used for checking the wireless communication signal strength, the electric quantity, the temperature and the humidity and the vibration acceleration of each node in real time.

Further, the radioactive source node monitoring unit is completed through a node view; the node view adopts character display and color display.

Further, the radiation source node monitoring unit further includes a node management function, specifically: add nodes, delete nodes, search nodes, and node attribute details.

Further, the radiation source node view is done through a mapping function; the plotting function is used to plot a graph and a report.

The radiation source management system further comprises a mobile APP based on an Android system; the APP is used for checking the node state of the radioactive source in real time.

The beneficial effects provided by the invention are as follows: the complete set of complete radioactive source management system is provided, humanization and intellectualization are realized, and the state information of temperature and humidity, displacement early warning and the like of any monitoring node can be checked in real time.

Drawings

FIG. 1 is a block diagram of a radiation source management system of the present invention;

FIG. 2 is a block diagram of the login unit design of the present invention;

FIG. 3 is a block diagram of the design of a node monitoring unit of the radiation source of the present invention;

FIG. 4 is a block diagram of the node management function design of the present invention;

FIG. 5 is a block diagram of a log cell design;

FIG. 6 is a block diagram of a design of radiation source management system communication functions.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, embodiments of the present invention will be further described with reference to the accompanying drawings.

Referring to fig. 1, a radiation source management system for providing a human-friendly operation interface includes the following units:

the system comprises a login unit, a radioactive source node monitoring unit, a log unit, a permission management unit and a communication unit.

The login unit is used for logging in the system;

the radioactive source node monitoring unit comprises radioactive source node early warning and radioactive source node checking;

the radioactive source node early warning comprises the following steps: temperature and humidity abnormity early warning, radioactive source abnormal vibration early warning and radioactive source out-of-control alarm; after the alarm condition appears, the color of the icon representing the radioactive source node changes, and a manager is prompted to perform safety check on the corresponding radioactive source;

the radioactive source nodes look over the wireless communication signal strength, electric quantity, temperature and humidity and vibration acceleration of each node in real time.

The log unit includes: system operation logs, alarm logs and shift log;

in the system operation log interface, all operation logs of the system can be checked, such as all user registration information, all types of alarm information, alarm action sending information and the like, date retrieval and keyword retrieval are supported, and a word report can be generated from the system operation logs. The data can be kept and checked for a long time, and trace analysis and management are facilitated.

On an alarm log interface, all alarm logs of the system can be checked, such as temperature and humidity abnormal alarm, abnormal movement alarm, heartbeat signal loss alarm and the like, three types of retrieval modes of a terminal, a state, date and the like are supported, and a word report can be generated from the alarm logs.

On the 'shift log' interface, all shift logs of the system can be checked, date retrieval is supported, and a word report can be generated from the shift logs. The data can be kept and checked for a long time, and trace analysis and management are facilitated.

The authority management unit comprises personnel setting and account setting;

the user with the highest administrative authority may operate the "personnel settings". The method is mainly used for adding, modifying and deleting the information and the authority of the radioactive source management personnel, including the name, the duty, the description of the duty, the telephone number of the management personnel and whether to receive the alarm short message. If the person chooses to receive the alarm short message, the person receives the alarm short message when alarming.

The user with administrator authority may operate "account management" and may add, modify, delete the name, password, and account type of the system operation maintenance personnel.

The communication unit includes TCP/IP communication and GSM network communication.

Referring to fig. 2, fig. 2 is a block diagram of a login unit according to the present invention.

After the radiation source management system is started, a login interface is displayed firstly. At this time, the user needs to input a correct user name and password before entering the system to check node information and management personnel, the functional design block diagram is shown in fig. 2, and the specific flow is as follows:

(1) firstly, a user inputs an account and a password of the user, and a program enters a background authentication system after the user clicks login.

(2) The system finds the encrypted password corresponding to the account number, namely the MD5 value in the SQL database through the account number input by the user, when the value is preset password, the value is obtained through the MD5 encryption algorithm and stored in the SQL database, and the encrypted MD5 value is obtained through the MD5 algorithm on the spot of the password input by the user.

(3) And comparing the two MD5 values to determine whether the user inputs the correct password.

Referring to fig. 3, fig. 3 is a block diagram of a radiation source node monitoring unit according to the present invention; the radioactive source node monitoring unit is completed through a node view; the view of the radioactive source monitoring node adopts a scheme of 'text display + color display', a design prototype control of the radioactive source monitoring node is a basic button, and the required functions are realized by inheriting the button on a program and rewriting some internal methods of the button, and the specific flow is as follows:

(1) and the monitoring node control inherits the basic Button control, so that the node control generates a Button click special effect when clicking.

(2) Some private variables are added to the node for storing the required sensor data and node state. The sensor data and the node state set in the node can be viewed in the node viewing unit.

(3) Adding a private method setParam () to the node for setting the sensor data and the node state in the step 2), and calling the parent () method, namely view invalidation, so that the system calls the redrawing method OnPaint () of the control.

(4) Rewriting the OnPaint () method of the parent class to enable the node control element to generate a desired view effect, wherein the main method is divided into two steps, the state of the node is checked in the OnPaint () method, and different colors are displayed according to different states; the sensor data is selectively text displayed according to the global settings.

The radioactive source node monitoring unit further comprises a node management function, and specifically comprises the following steps: add nodes, delete nodes, search nodes, and node attribute details.

Referring to fig. 4, fig. 4 is a block diagram of a node management function design according to the present invention; the node management is mainly responsible for node layout management, and comprises the steps of calculating a row of node views to be placed in a plate and the position of each node view, and dynamically changing the layout of the node views in real time according to the change of the size of the plate. The specific program design flow is as follows:

(1) when a user uses the function of adding the nodes, background software calculates the drawing coordinates of the newly added sub-nodes through internal subprogram layout management, automatically judges whether the original node view needs to be rearranged or not, and then adds the newly created node view into the node view list for unified management.

(2) When a user uses the function of deleting nodes, background software firstly searches a node view List List < NodeView > to find a node object which needs to be deleted by the user, then removes the node object from the List, and simultaneously judges whether the node arrangement needs to be adjusted or not by self through a 'layout management' subprogram.

(3) When the user uses the node searching function, the background program directly searches the node view list to find the node object which the user needs to view, and then focuses through an internal Focus () method to make the node object be highlighted in front of the user.

(4) And displaying the node attribute details. The method is realized by property control ProperteAdv carried by WinForm, adds self-defined property to ProperteAdv, namely the parameters of the node needing to be displayed completely, and then dynamically binds the binding object of ProperteAdv to the node needing to be displayed in detail.

The log unit is used for recording all events in the software running process, so that query and report generation can be facilitated in the future, and the log unit has the functions of recording login days, shift log, alarm log, log keyword accurate retrieval, keyword fuzzy retrieval, date retrieval and word report generation. Referring to fig. 5, fig. 5 is a block diagram of a log unit design, which is specifically designed as follows:

(1) the system operation events comprise user login and logout, user addition and deletion and node various alarms. The specific format of the log is 'time + object + event', and the data is inserted into the SQL database through SQL statements.

(2) When the user clicks the log query button (all logs, alarm logs and shift-to-shift logs), the background software extracts the required entries from the database by SQL query statements plus specified filter conditions (depending on the button pressed).

(3) If the user also adds the retrieval condition, the background program also adds the filtering conditions such as accurate keywords, fuzzy keywords, time zones and the like on the basic SQL query statement.

(4) And finally, inquiring the obtained conforming data table, and binding the data table with a list display control DataGribView, so that the log can be orderly displayed in front of a user.

The communication unit comprises TCP/IP network communication and GSM network communication, the TCP/IP network communication specifically uses a UDP protocol and a TCP protocol, a UDP user node is communicated with a server, and the TCP is used for communication between a mobile phone end and the server; the GSM network communication is used for reporting the alarm short message to the mobile phone. Fig. 6 shows a block diagram of the design of the communication function of the radiation source management system, and the specific design flow is as follows:

(1) the UDP protocol is adopted by the messages sent by the node group, when the server receives the data packets by the program monitoring thread, the data packets are not processed immediately but lost to the message queue, and the reason for doing so is to prevent the server from losing the packets due to the fact that the data packets are not processed when a plurality of nodes of the node group send effective data packets almost simultaneously. The data packets of the message queue are processed sequentially by another thread, the processing mode is to decode the data packets according to a predetermined packet format, and then perform subsequent operations, and the specific data format is "data + unit + space", for example:

001#12.3℃26.9％8.6μW

wherein the unit of node numbering is "#", and the order of occurrence between data does not matter.

(2) If necessary alarm is found and short message is sent after processing in the received node data, then message is sent to GSM, and the GSM module sends short message to the appointed mobile phone number. The communication mode adopted between the GSM module and the GSM thread is serial COM port communication.

(3) The mobile phone end can check node data through the APP remote login server, the adopted network protocol TCP is adopted, the server end supports multipoint simultaneous login, when one mobile phone passes through the APP login system, software can maintain a new communication thread for the mobile phone, and the mobile phone is placed in a thread pool to be managed in a unified mode, and therefore the problem that communication of each mobile monitoring terminal and the server interferes mutually is avoided.

The radioactive source node viewing is completed through a drawing function; the plotting function is used to plot graphs and reports. Referring to fig. 7, fig. 7 is a diagram of a functional diagram of a drawing according to the present invention. The drawing function is mainly used for drawing a temperature and humidity curve graph, besides, a vibration drawing graph and an energy collection graph are supported, the display in a daily, weekly and monthly mode is supported, a report graph is generated, and the drawing function is realized by adopting a Chart control Chart carried by Winform, and the drawing function specifically comprises the following steps:

(1) first when the user adds a node to be mapped and selects a date and reporting mode (daily, weekly or monthly).

(2) And the background software generates an SQL query statement through a related subprogram according to the filtering condition input by the user and is used for querying the node data meeting the requirement to the SQL database.

(3) The node data is bound to curve objects Series in the program, namely, each type of data (such as temperature and humidity) of each node corresponds to one Series object.

(4) And then adding all Series objects to corresponding icons Chart, wherein each data corresponds to one Chart, one Chart can simultaneously draw one sensor data of a plurality of nodes, for example, Chart1 draws a temperature curve, Chart2 draws a humidity curve, Chart3 draws a vibration acceleration curve, and Chart4 draws a power curve for collecting electromagnetic wave energy.

(5) Finally, if the user needs to generate a daily report, a weekly report or a monthly report, the picture can be printed into a JPEG picture, so that the picture is convenient to store and browse.

In addition, the system also develops a set of radioactive source monitoring management APP based on the android operating system, and packages the software into an APK installation package, so that the software can be installed on any android mobile terminal. A user utilizes the mobile terminal to connect into the wireless local area network, and can check the state information of temperature and humidity, displacement early warning and the like of any monitoring node in real time through the software APP.

The main functions of the mobile terminal monitoring software APP are similar to those of server-side software, but the mobile terminal monitoring software APP is more simplified. Many operations and settings are all accomplished at the server side, and the APP side only carries out simple demonstration work, divide into three bold according to the function: login function, status display, drawing and communication function.

The main functions of APP are:

(1) a message reception display function. And receiving, storing and displaying messages from the nodes in real time, wherein the messages comprise temperature and humidity, vibration acceleration, signal strength, energy collection and other information.

(2) A graphical display function. The temperature and humidity information of each node can be visually displayed in a graphic mode.

(3) A connection status and node number display function. The network connection state can be displayed, and the software can automatically reestablish the connection after the disconnection; the number of nodes currently online can be displayed.

The drawing function of the APP end is mainly used for drawing a temperature and humidity curve graph, and besides, a drawing vibration graph and an energy collection graph are supported, and the drawing vibration graph and the energy collection graph are achieved by adopting a third-party graph control MPAndriodcart.

The communication function of the APP end is mainly TCP communication and is used for logging in a server and inquiring node data of a server database, but in a test mode, UDP communication is supported at all and is used for skipping over the server to directly receive the node data, and the function is only used when nodes of the Internet of things are debugged and deployed. The communication function is specifically designed as follows:

(1) in normal use, when a user inputs necessary login information, the UI thread generates a callback event, which is ignored by the drawing thread and directed to the processing thread.

(3) After analyzing the event type, the processing thread discards the package to the message queue.

(3) And then the message is acquired by the TCP thread, so that a TCP login request is generated for the server, and a safe TCP connection channel is established with the server after the login is passed, so as to perform subsequent data interaction.

(4) When the user clicks the node view, the background program generates a TCP data request through the link and sends an SQL data query request to the server.

(5) After the query is completed, the data reaches the TCP thread from the server, and then enters a message queue.

(6) After the processing thread extracts the message from the message queue, the processing thread analyzes the message to obtain the drawing data and turns to the drawing thread.

(7) And formally starting to create the icon object after the drawing thread obtains the node data, and adding the data into the chart for displaying.

The invention has the beneficial effects that: the complete set of complete radioactive source management system is provided, humanization and intellectualization are realized, and the state information of temperature and humidity, displacement early warning and the like of any monitoring node can be checked in real time.

The above description is only exemplary of the present invention and should not be taken as limiting, and any modifications, equivalents, improvements and the like that are within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (8)

1. A radiation source management system is based on a Windows server and is characterized in that: the method comprises the following steps: the system comprises a login unit, a radioactive source node monitoring unit, a log unit, a permission management unit and a communication unit. The login unit is used for logging in the system; the radioactive source node monitoring unit comprises radioactive source node early warning and radioactive source node checking; the log unit includes: system operation logs, alarm logs and shift log; the authority management unit comprises personnel setting and account setting; the communication unit includes TCP/IP communication and GSM network communication.

2. The radiation source management system defined in claim 1, wherein: the login unit is used for inputting an account and a password and judging whether login authority is provided or not by verifying an MD5 value corresponding to the account and the password; if the MD5 values corresponding to the account number and the password are consistent with the MD5 value preset to the SQL database, the system is successfully accessed through verification, otherwise, the verification fails.

3. The radiation source management system defined in claim 1, wherein: the radioactive source node early warning comprises the following steps: temperature and humidity abnormity early warning, radioactive source abnormal vibration early warning and radioactive source out-of-control alarm.

4. The radiation source management system defined in claim 1, wherein: the radioactive source nodes look over the wireless communication signal strength, electric quantity, temperature and humidity and vibration acceleration of each node in real time.

5. The radiation source management system defined in claim 1, wherein: the radioactive source node monitoring unit is completed through a node view; the node view adopts character display and color display.

6. The radiation source management system defined in claim 1, wherein: the radioactive source node monitoring unit further comprises a node management function, and specifically comprises the following steps: add nodes, delete nodes, search nodes, and node attribute details.

7. The radiation source management system defined in claim 4, wherein: the radioactive source node viewing is completed through a drawing function; the plotting function is used to plot graphs and reports.

8. The radiation source management system defined in claim 1, wherein: the radiation source management system further comprises a mobile APP based on an Android system; the APP is used for checking the node state of the radioactive source in real time.

Images