CN204613411U - Based on the radiation source monitoring system of Internet of Things - Google Patents
Based on the radiation source monitoring system of Internet of Things Download PDFInfo
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- CN204613411U CN204613411U CN201520308402.8U CN201520308402U CN204613411U CN 204613411 U CN204613411 U CN 204613411U CN 201520308402 U CN201520308402 U CN 201520308402U CN 204613411 U CN204613411 U CN 204613411U
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Abstract
The utility model provides a kind of radiation source monitoring system based on Internet of Things, comprising: distribute the field monitoring terminal, transmission network and the remote monitoring server that are arranged on each monitoring point; Described in each, field monitoring terminal is connected with described remote monitoring server by described transmission network; The radiation source monitoring system based on Internet of Things that the utility model provides has the following advantages: (1) field monitoring terminal joint adopts radiation dose rate measuring instrument and video capture device, can monitor radiation source comprehensively, pass through communication network again, make long-rangely to know monitoring information in time, effectively improve monitoring efficiency; (2) communication network adopts wired or wireless network flexibly, has the advantage of the easy deployment maintenance of radiation source monitoring system based on Internet of Things; (3) field monitoring terminal adopts the power supply of wind energy and solar combined power generating, has the advantage that energy consumption is low.
Description
Technical field
The utility model belongs to radiation source monitoring technical field, is specifically related to a kind of radiation source monitoring system based on Internet of Things.
Background technology
Along with China's expanding economy, radiation source in industrial enterprise and x-ray apparatus also get more and more, radiation source not only at nuclear facilities, and is all applied in all trades and professions such as research institutions, medical institutions, geology and coal exploration and exploitation, oil exploitation and oil refining, highways and bridges construction, machine-building and installations.
Not only radiativity pollutes and has following characteristics: radiativity pollutes and colourless, is tastelessly difficult to discover, with physical form but also with form of energy harm public health with destroy the ecologic equilibrium in invisible; And environment will be once will be difficult to administer and recover by its pollution; Meanwhile, it has social sensitivity, and the public has abnormal fear sense to radiativity, once find radiativity contamination hazard, very easily cause society uneasy, impact is stable.
Therefore, radiation source is effectively monitored, prevent radiativity contamination accident, significant.In prior art, the monitoring of radiation source is in backward personal monitoring's stage always, has the problem that monitoring efficiency is extremely low, how effectively to improve radiation source monitoring efficiency, and stopping radiation source and lose and reveal, is current problem demanding prompt solution.
Utility model content
For the defect that prior art exists, the utility model provides a kind of radiation source monitoring system based on Internet of Things, can effectively solve the problem.
The technical solution adopted in the utility model is as follows:
The utility model provides a kind of radiation source monitoring system based on Internet of Things, comprising: distribute the field monitoring terminal, transmission network and the remote monitoring server that are arranged on each monitoring point; Described in each, field monitoring terminal is connected with described remote monitoring server by described transmission network;
Wherein, described field monitoring terminal comprises radiation dose rate measuring instrument, video capture device, GPS locator, controller, onsite alarming device, communication interface and power supply; Described processor is connected with described radiation dose rate measuring instrument, described video capture device, described GPS locator, described onsite alarming device, described communication interface and described power supply respectively.
Preferably, described onsite alarming device is audible-visual annunciator.
Preferably, described power supply is wind energy and sun power integral type power supply.
Preferably, described radiation dose rate measuring instrument comprises G-M counter tube and scintillator detector.
Preferably, also described field monitoring terminal also comprises shell; Described shell is radiation hardness, protection against the tide, anticorrosion, high temperature-proof, against shock, dust-proof, oil-stain-preventing and explosion-proof shell.
Preferably, described transmission network includes transmission network network and wireless-transmission network.
Preferably, described wire transmission network comprises fiber optic network or Asymmetrical Digital Subscriber Line ADSL network; Described wireless-transmission network comprises GPRS network, 3G network or WIFI network.
The radiation source monitoring system based on Internet of Things that the utility model provides has the following advantages:
(1) field monitoring terminal joint adopts radiation dose rate measuring instrument and video capture device, can monitor radiation source comprehensively, then by communication network, makes long-rangely to know monitoring information in time, effectively improves and monitors efficiency;
(2) communication network adopts wired or wireless network flexibly, has the advantage of the easy deployment maintenance of radiation source monitoring system based on Internet of Things;
(3) field monitoring terminal adopts the power supply of wind energy and solar combined power generating, has the advantage that energy consumption is low.
Accompanying drawing explanation
The structural representation of the radiation source monitoring system based on Internet of Things that Fig. 1 provides for the utility model.
Embodiment
Below in conjunction with accompanying drawing, the utility model is described in detail:
Composition graphs 1, the utility model provides a kind of radiation source monitoring system based on Internet of Things, comprising: distribute the field monitoring terminal, transmission network and the remote monitoring server that are arranged on each monitoring point; Each field monitoring terminal is connected with remote monitoring server by transmission network;
Wherein, field monitoring terminal comprises radiation dose rate measuring instrument, video capture device, GPS locator, controller, onsite alarming device, communication interface and power supply; Processor is connected with radiation dose rate measuring instrument, video capture device, GPS locator, onsite alarming device, communication interface and power supply respectively.
In practical application, onsite alarming device adopts audible-visual annunciator.
Power supply is wind energy and sun power integral type power supply, thus effectively reduces the energy consumption of field monitoring terminal, ensures the lasting non-stop run in 24 hours of field monitoring terminal, avoids staff frequently to change battery simultaneously.
Radiation dose rate measuring instrument comprises G-M counter tube and scintillator detector.Wherein, G-M counter tube is Geiger--Miller (Geiger--Muller) counter tube, being called for short G--M counter tube, is a kind of nuclear radiation detector of practicality.G--M counter tube belongs to the detector of gas counter, and its operation material is gas, and its function is the quantity of recording ray particle, but can not distinguish the energy of particle.Scintillator detector is the radiation detector primarily of the collecting part of scintillator, light and electrooptical device composition.When particle enters scintillator, atom or the molecule of scintillator are excited and produce fluorescence.
Field monitoring terminal also comprises shell; Shell is radiation hardness, protection against the tide, anticorrosion, high temperature-proof, against shock, dust-proof, oil-stain-preventing and explosion-proof shell.Thus effectively extend the serviceable life of monitoring terminal, improve the functional reliability of monitoring terminal.
Transmission network includes transmission network network and wireless-transmission network.Wire transmission network comprises fiber optic network or Asymmetrical Digital Subscriber Line ADSL network; Wireless-transmission network comprises GPRS network, 3G network or WIFI network.The type that transmission network specifically adopts, according to the kind of radiation source and flexible design, such as, for Fixed Emitter and half mobile radiation source, field condition is relatively stable, wire transmission (telecommunications 2M) can be adopted to be main, the place that subnetwork cannot arrive, the mode of the 3G wireless communication networks of telecommunications can be adopted.And for mobile radiation source, field monitoring, because being limited by the factor such as field condition and monitoring technology, therefore, all adopts 3G wireless communication networks to build.
The radiation source monitoring system based on Internet of Things that the utility model provides has the following advantages:
(1) field monitoring terminal joint adopts radiation dose rate measuring instrument and video capture device, can monitor radiation source comprehensively, then by communication network, makes long-rangely to know monitoring information in time, effectively improves and monitors efficiency;
(2) communication network adopts wired or wireless network flexibly, has the advantage of the easy deployment maintenance of radiation source monitoring system based on Internet of Things;
(3) field monitoring terminal adopts the power supply of wind energy and solar combined power generating, has the advantage that energy consumption is low.
The above is only preferred implementation of the present utility model; it should be pointed out that for those skilled in the art, under the prerequisite not departing from the utility model principle; can also make some improvements and modifications, these improvements and modifications also should look protection domain of the present utility model.
Claims (7)
1. based on a radiation source monitoring system for Internet of Things, it is characterized in that, comprising: distribute the field monitoring terminal, transmission network and the remote monitoring server that are arranged on each monitoring point; Described in each, field monitoring terminal is connected with described remote monitoring server by described transmission network;
Wherein, described field monitoring terminal comprises radiation dose rate measuring instrument, video capture device, GPS locator, controller, onsite alarming device, communication interface and power supply; Described processor is connected with described radiation dose rate measuring instrument, described video capture device, described GPS locator, described onsite alarming device, described communication interface and described power supply respectively.
2. the radiation source monitoring system based on Internet of Things according to claim 1, is characterized in that, described onsite alarming device is audible-visual annunciator.
3. the radiation source monitoring system based on Internet of Things according to claim 1, is characterized in that, described power supply is wind energy and sun power integral type power supply.
4. the radiation source monitoring system based on Internet of Things according to claim 1, is characterized in that, described radiation dose rate measuring instrument comprises G-M counter tube and scintillator detector.
5. the radiation source monitoring system based on Internet of Things according to claim 1, is characterized in that, also described field monitoring terminal also comprises shell; Described shell is radiation hardness, protection against the tide, anticorrosion, high temperature-proof, against shock, dust-proof, oil-stain-preventing and explosion-proof shell.
6. the radiation source monitoring system based on Internet of Things according to claim 1, it is characterized in that, described transmission network includes transmission network network and wireless-transmission network.
7. the radiation source monitoring system based on Internet of Things according to claim 6, is characterized in that, described wire transmission network comprises fiber optic network or Asymmetrical Digital Subscriber Line ADSL network; Described wireless-transmission network comprises GPRS network, 3G network or WIFI network.
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| Application Number | Priority Date | Filing Date | Title |
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| CN201520308402.8U CN204613411U (en) | 2015-05-14 | 2015-05-14 | Based on the radiation source monitoring system of Internet of Things |
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Cited By (3)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN106443748A (en) * | 2016-08-19 | 2017-02-22 | 黑龙江省科学院技术物理研究所 | High-precision wireless radiation dosage monitoring device and method |
| CN109031392A (en) * | 2018-06-25 | 2018-12-18 | 郑州云启工业设备技术有限公司 | A kind of radiation detection interlink warning method based on distance |
| CN111327700A (en) * | 2020-02-26 | 2020-06-23 | 武汉工程大学 | Multipoint radiation remote monitoring system and method |
-
2015
- 2015-05-14 CN CN201520308402.8U patent/CN204613411U/en active Active
Cited By (4)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN106443748A (en) * | 2016-08-19 | 2017-02-22 | 黑龙江省科学院技术物理研究所 | High-precision wireless radiation dosage monitoring device and method |
| CN109031392A (en) * | 2018-06-25 | 2018-12-18 | 郑州云启工业设备技术有限公司 | A kind of radiation detection interlink warning method based on distance |
| CN109031392B (en) * | 2018-06-25 | 2020-09-08 | 南京溧水高新创业投资管理有限公司 | Radiation detection linkage alarm method based on distance |
| CN111327700A (en) * | 2020-02-26 | 2020-06-23 | 武汉工程大学 | Multipoint radiation remote monitoring system and method |
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