CN206212180U - Hydrology multi-antenna - Google Patents
Hydrology multi-antenna Download PDFInfo
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- CN206212180U CN206212180U CN201621310954.3U CN201621310954U CN206212180U CN 206212180 U CN206212180 U CN 206212180U CN 201621310954 U CN201621310954 U CN 201621310954U CN 206212180 U CN206212180 U CN 206212180U
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Abstract
The utility model is related to a kind of hydrology multi-antenna, including:Front end monitoring subsystem, it includes each monitoring device being arranged in Hydrologic monitoring station, and each monitoring device includes at least one in robot radar ripple tachymeter, robot radar ripple water-level gauge and video camera;Transmission subsystem, is connected with front end monitoring subsystem, and transmission subsystem includes OTN backbone networks, and OTN backbone networks are used to transmit at least one in the hydrographic information data of the Hydrologic monitoring station acquired in the monitoring device, video and image to center subsystem;Center subsystem, is connected with transmission subsystem, for receiving, storing and shows at least one in hydrographic information data, video and the image of the Hydrologic monitoring station.In the utility model, hydrology multi-antenna is based on OTN backbone networks, and video acquisition, hydrographic information data acquisition have been carried out into effective fusion, treatment, realizes the visual long-range monitoring of Hydrologic monitoring station with control.
Description
Technical field
The utility model is related to hydrologic monitoring field, more particularly to a kind of hydrology multi-antenna.
Background technology
To adapt to flood control and the modernization of water project operation, information-based requirement, the automatic Building of hydrologic monitoring system is configured to
The need for era development.The collection of the multinomial Monitoring Data such as flow velocity, water level, water quality, flow, precipitation and remote visualization are to prison
It is being necessarily required to for hydrology modernization to survey networking.
Hydrology automatic monitoring system is made up of monitoring center, communication network, front end monitoring device, the part of measuring apparatus four.
Traditional monitoring systematic communication network using GPRS (General Packet Radio Service, general packet radio service) and
Big-dipper satellite, does not form integrated network platform.Front end monitoring device includes robot radar ripple tachymeter, robot radar ripple water
The monitoring devices such as position meter, but data platform do not merge, and do not possess visual remote manipulation function.
Utility model content
According to an embodiment of the present utility model, there is provided a kind of hydrology multi-antenna, including:
Front end monitoring subsystem, it includes each monitoring device being arranged in Hydrologic monitoring station, each monitoring device bag
Include at least one in robot radar ripple tachymeter, robot radar ripple water-level gauge and video camera;
Transmission subsystem, is connected with the front end monitoring subsystem, and the transmission subsystem includes that optical transfer network OTN is key
Net, the OTN backbone networks are used for the hydrographic information data of the Hydrologic monitoring station acquired in the monitoring device, video and image
In at least one transmit to center subsystem;
The center subsystem, is connected with the transmission subsystem, for receiving, storing and shows the Hydrologic monitoring station
Hydrographic information data, video and image at least one.
For said system, in a kind of possible implementation, the robot radar ripple tachymeter is suspended on tested Jie
On cableway above matter.
For said system, in a kind of possible implementation, the robot radar ripple water-level gauge includes probe, transmitting
Machine, transmitting antenna, receiver, reception antenna, processor and display;
Wherein, the emitter, the receiver, the processor and the display are integrated in cabinet, the hair
Penetrate antenna to be connected with the emitter, the reception antenna is connected with the receiver, the transmitting antenna and the reception day
Line exposes from cabinet top, and the cabinet is installed in vertical rod, and the probe is installed on from the vertical rod to measured medium
On the cross bar that surface extends.
For said system, in a kind of possible implementation, the front end monitoring subsystem also includes:
Uninterrupted power source, for providing back-up source for each monitoring device.
For said system, in a kind of possible implementation, the front end monitoring subsystem also includes and the OTN
The network equipment of backbone network connection, lightning protection device is provided with the network equipment.
For said system, in a kind of possible implementation, the center subsystem includes that storage part, video are decoded
Spell control portion, large-size screen monitors display part, management platform and remote control portion.
For said system, in a kind of possible implementation, the storage part is stored including centre grade video network
Equipment, i.e. CVR, the CVR are used to that the hydrographic information data, video and the image that receive to be stored and backed up.
For said system, in a kind of possible implementation, the management platform includes intelligent amended record equipment, described
Intelligent amended record equipment is connected with the CVR.
For said system, in a kind of possible implementation, control portion is spelled in the video decoding includes Video Decoder,
The Video Decoder connects the large-size screen monitors display part by DVI, HDMI or USB interface.
For said system, in a kind of possible implementation, the remote control portion surveys with the robot radar ripple
Fast instrument and the video camera are communicated, for carrying out remote control to the robot radar ripple tachymeter and video camera.
In the utility model, hydrology multi-antenna is based on OTN backbone networks, by video acquisition, hydrographic information
Data acquisition has carried out effective fusion, treatment, realizes the visual long-range monitoring of Hydrologic monitoring station with control.
According to below with reference to the accompanying drawings to detailed description of illustrative embodiments, further feature of the present utility model and aspect will
It is made apparent from.
Brief description of the drawings
Comprising in the description and accompanying drawing and the specification of the part that constitutes specification together illustrates this practicality newly
The exemplary embodiment of type, feature and aspect, and for explaining principle of the present utility model.
Fig. 1 shows the structural representation of the hydrology multi-antenna according to the embodiment of the utility model one.
Fig. 2 shows the network structure of the hydrology multi-antenna according to the embodiment of the utility model one.
Fig. 3 is the overall structure diagram that wireless remote control radar wave digitizes flow measurement instrument system.
Fig. 4 is robot radar ripple water-level gauge overall structure diagram.
Fig. 5 shows the system knot of the Surveillance center of the hydrology multi-antenna according to the embodiment of the utility model one
Composition.
Fig. 6 shows the storage part of the Surveillance center of the hydrology multi-antenna according to the embodiment of the utility model one
The structural representation for dividing.
Fig. 7 shows the signal of the data backup of the hydrology multi-antenna according to the embodiment of the utility model one
Figure.
Fig. 8 shows the signal of the intelligent amended record of the hydrology multi-antenna according to the embodiment of the utility model one
Figure.
Specific embodiment
Various exemplary embodiments of the present utility model, feature and aspect are described in detail below with reference to accompanying drawing.In accompanying drawing
Identical reference represents the same or analogous element of function.Although the various aspects of embodiment are shown in the drawings,
It is unless otherwise indicated, it is not necessary to accompanying drawing drawn to scale.
Special word " exemplary " means " being used as example, embodiment or illustrative " herein.Here as " exemplary "
Illustrated any embodiment should not necessarily be construed as preferred or advantageous over other embodiments.
In addition, in order to better illustrate the utility model, given in specific embodiment below numerous specific
Details.It will be appreciated by those skilled in the art that without some details, the utility model can equally be implemented.In some realities
In example, it is not described in detail for method well known to those skilled in the art, means, element and circuit, in order to highlight this reality
With new purport.
OTN (Optical Transport Network, optical transfer network), is based on wavelength-division multiplex technique, in photosphere
The transmission net of network is organized, is follow-on Backbone Transport Network.The major advantage of OTN is complete back compatible.OTN can set up
In existing SONET (Synchronous Optical Network, Synchronous Optical Network)/SDH (Synchronous
Digital Hierarchy, SDH) on the basis of management function, provide not only presence communication protocol it is complete
It is transparent, but also for WDM provides connection and networking capability end to end.OTN is ROADM (Reconfigurable Optical
Add-Drop Multiplexer, ROADM) specification of photosphere interconnection is provided, and converged supplemented with wavelet length
With the ability of dredging.
The utility model is carried out the digitlization hydrology automated monitor such as robot radar ripple tachymeter using OTN backbone networks
Combination constitutes monitoring network, realizes wired networking, then is communicated with optical fiber private-line mode and Surveillance center by network coordinator,
So as to build a visualization hydrology multi-antenna based on OTN backbone networks.
Visualization hydrology multi-antenna is to solve hydrology automation, visualization, the optimal path of modernization, energy
Hydrologic monitoring ability is enough lifted, the long-term situation for relying on and manually observing and predicting fundamentally is changed, test personnel can be with remote operation
Flow measuring device carries out hydrologic survey, has both improved the ageing of hydrologic survey, in turn ensure that the accuracy of test data.System is not only
The scientific and technological content of monitoring means can be improved, perfect automation hydrology monitoring system structure has been also set up, to realizing comprehensive water
Literary monitoring network, to the aspect important in inhibiting such as Flood Pre-warning System, command scheduling, water environment protection.
Fig. 1 shows the structural representation of the hydrology multi-antenna according to the embodiment of the utility model one.Such as Fig. 1
Shown, the hydrology multi-antenna can include:
Front end monitoring subsystem 11, it includes each monitoring device being arranged in Hydrologic monitoring station, each monitoring device
Including at least one in robot radar ripple tachymeter, robot radar ripple water-level gauge and video camera;
Transmission subsystem 13, is connected with the front end monitoring subsystem 11, and the transmission subsystem 13 includes optical transfer network
OTN backbone networks, the OTN backbone networks are used for the hydrographic information data of the Hydrologic monitoring station acquired in the monitoring device, regard
At least one in frequency and image is transmitted to center subsystem;
The center subsystem 15, is connected with the transmission subsystem 13, for receiving, storing and shows hydrology prison
At least one in the hydrographic information data of survey station, video and image.
Wherein, hydrographic information data (or being hydrographic data) can include the quilt that for example robot radar ripple tachymeter is measured
Survey the flow velocity of medium, and the water level of measured medium that measures of robot radar ripple water-level gauge etc..
As shown in Fig. 2 the network structure to visualize hydrology multi-antenna.In the present embodiment, the hydrology
Multi-antenna can be by front end monitoring subsystem (or front end subsystem, front end etc.), transmission subsystem and center
Subsystem (or being administrative center, Surveillance center, center etc.) three parts are constituted.
(1) front end subsystem.
Front end subsystem can be including being deployed in the monitoring device of each Hydrologic monitoring station (or being hydrometric station, monitoring station etc.)
(or being headend equipment) robot radar ripple tachymeter, robot radar ripple water-level gauge, video camera etc., can in real time by hydrologic monitoring
The Monitoring Data stood, video, image reach administrative center.For example, as shown in Fig. 2 headend equipment can include but not limit
In video conference device, digital communication equipment, high velocity star ball grinder, cylinder machine, high speed variable Jiao's cylinder machine, radar wave tachymeter, benefit
Light lamp, rainfall gauge, water-level gauge etc..
(2) Transmission system.
Hydrology multi-antenna can be carried on the OTN backbone networks of operator, for front end and platform (i.e. center
Subsystem) between communication.
(3) center subsystem.
Center can be carried out using CVR (Central Video Recorder, centre grade video network storage device) etc.
Storage, large screen splicing show.Surveillance center is deployed with the service end and client of monitor supervision platform, the data that receiving front-end is uploaded,
And be managed.Administrative center can also be used for including acquisition server, application server, database server, work station etc.
Carry out Hydrological Data Acquisition and treatment.Center can realize real-time monitoring, information inquiry, Information Statistics, information analysis, pipe on duty
The functions such as reason, short message managing, system administration.Video data is acquired and process when, can be by decoder to regarding
Frequency is decoded, and is then forwarded to video wall (such as large-screen display) and is shown.
The characteristics of hydrology multi-antenna of the present embodiment, includes:
(1) efficiently:Each AS depth integration
Platform provides the infrastructure device management and control work(such as all kinds of coding/decoding apparatus management, storage management, network management, alarming and managing
Energy.Unified monitoring, control are carried out to each subsystem simultaneously and is managed, can be multiple auxiliary with compatible video monitoring, Based Intelligent Control etc.
Help service application subsystem.Make hydrometric station do not rely on people even independently of people in the case of realize different system between intelligence
Linkage.
(2) safety:Effective Data Security
System has effective Data Security, by authentication and rights management, it is ensured that just may be used after user authentication
To enter system, into system after also need strict implement access rights and administration authority.Priority assignation is using encryption multi-level, high
Technology, to ensure the functions such as the safety that system each unit is run, simultaneity factor User logs in, operation, configuration all using strict
Transmission encryption mechanism.For data storage, stored using hydrology station distributed storage+central site network, and by hard disk protection
Mechanism, RAID (Redundant Array of Independent Disk, raid-array) 5 technologies, it is ensured that data
Will not lose.
(3) it is reliable:Perfect operation management mechanism
Platform can provide perfect comprehensively monitoring and operation management function, be capable of achieving to video equipment, monitoring device, right
Overall monitor and the management of the various resources such as equipment, the network equipment, storage device, server, Database Systems are said, monitoring is reached
The visualization of system, controllableization and automatic management purpose.Platform helps O&M departments at different levels quickly to position failure, rapid to recover
Supervisory control system running environment, and the procedure operation management for passing through specification, by management data electronization, management process specification,
So as to build unified, perfect, active procedure O&M, Standardization Service and centralized management for the whole network running environment, comprehensively
Lifting operation management ability.
In a kind of possible implementation, the robot radar ripple tachymeter (or be robot radar ripple test flow velocity
Instrument, wireless remote control radar wave digitlization measurement instrument) it is suspended on the cableway above measured medium.
For example, wireless remote control radar wave digitlization measurement instrument, can be suspended on radar wave assignment test current meter
On the Simple steel wire cable road of supporting diameter 4.2mm, using wireless remote control, supporting positioning and flow measurement software, by computer (platform
Formula or notebook computer etc.) on remote operation, in a non contact fashion test and calculate such as river cross-section water surface flow velocity, section
Flow.Wireless remote control radar wave digitizes the overall structure diagram of flow measurement instrument system, as shown in Figure 3.
Wireless remote control radar wave digitlization measurement instrument solves rotating element current meter and ADCP (Acoustic Doppler
Current Profilers, acoustic Doppler fluid velocity profile instrument) in high flow rate, there is the water wave cannot to enter water, have floating object and pasture and water
Winding instrument can not test, it is dangerous the problems such as, it is possible to carry out remote control using remote desktop, realize the mesh of long-range flow measurement
's.
In a kind of possible implementation, as shown in figure 4, being robot radar ripple water-level gauge overall structure diagram.Institute
State robot radar ripple water-level gauge including robot radar ripple water-level gauge probe (level is kept during measurement), emitter, transmitting antenna, connect
Receipts machine, reception antenna, processor and display;
Wherein, the emitter, the receiver, the processor and the display are integrated in cabinet (as shown in Figure 4
Live cabinet) in, the transmitting antenna is connected with the emitter, and the reception antenna is connected with the receiver, described
Transmitting antenna and the reception antenna expose from cabinet top, and the cabinet is installed in vertical rod, and the probe is installed on
On the cross bar extended from the vertical rod to measured medium surface.
Additionally, robot radar ripple water-level gauge also include power-supply device (solar panels in such as Fig. 4), data record apparatus,
Anti-interference equipment (lightning rod in such as Fig. 4) auxiliary equipment.Communication interface supports GPRS communications, RS485 and RS232 communications;2
Road RS232 interfaces, 1 road RS485 interfaces etc..Additionally, vertical rod can be fixed near measured medium by ring flange etc., for example by
Survey the bank of the water surface.
As shown in figure 4, the narrow microwave pulse (radar wave in such as Fig. 4 of the probe emitter stage of robot radar ripple water-level gauge
Beam), this pulse, in spatial, runs into dielectric surface (such as peak level, lowest water level), its portion of energy quilt with the light velocity
Reflect, received by same probe.Transmitting pulse with receive the time interval of pulse and probe to measured medium surface away from
From being directly proportional, so as to calculate probe to the distance on measured medium surface.The antenna of robot radar ripple water-level gauge then can be used for
Send the data such as measured water level.
In a kind of possible implementation, front-end camera is mainly responsible for carrying out round-the-clock intelligent video to hydrometric station
Monitoring, while dual technology detector (being realized by video camera) can be set in hydrology station according to demand, is intruded into when there is personnel
Alarm is sent when in station, and alarm linkage is carried out with video monitoring system.
Coordinate data collection station to use using low-power consumption video camera in the bad monitoring station of condition of power supply, realize regarding
Frequently, the synchronous transfer of image and hydrographic information data etc..
The video camera disposed in the institute of hydrometric station can be with support area intrusion detecting, detecting of crossing the border, audio abnormity detecting, movement
The functions such as detecting, video shelter detecting, support that presetting bit is set, and support cruise scanning, and support Penetrating Fog, infrared light filling etc..
In a kind of possible implementation, the corollary equipment of front end monitoring subsystem can also include UPS
(Uninterruptible Power System, uninterrupted power source) is mainly each headend equipment and provides back-up source, there is provided 12
The power-on time of hour.
In a kind of possible implementation, the front end monitoring subsystem also includes what is be connected with the OTN backbone networks
The network equipment, lightning protection device is provided with the network equipment.
Further to improve the anti-lightning ability of system, in addition to each headend equipment need to possess lightning protection function, what vertical rod was installed
Other headend equipments can also install data, power supply two-in-one lightning additional.Device housings, vertical rod etc. carry out reliable ground.For example,
Each headend equipment is by network equipments such as interchanger, VPN (Virtual Private Network, Virtual Private Network), routers
Access OTN networks.Wherein, interchanger, VPN, router are desirably integrated into a cabinet, can set lightning-arrest on the cabinet
Device.
In the present embodiment, bearer network design can use the example below:
Headend equipment is by 485 communication protocols and telemetry terminal system (such as current meter, light compensating lamp in Fig. 2, rainfall gauge, water
Position meter etc.) RTU (Remote Terminal Unit, remote-terminal unit) serial ports connection, be directly accessed OTN backbone networks by water
Literary information data etc. reaches administrative center.
Video monitoring system bandwidth demand is closely related with resolution ratio and two factors of frame per second, according to actually required image
Real-time, fluency requirement are different.For example, video monitoring system requirement is in the case of 25 frames/s frame per second, CIF (Common
Intermediate Format, working standard form) (resolution ratio 352 × 288) code stream be 256Kbps, D1 (resolution ratio 720
× 576) code stream size be about 1Mbps, 720P (resolution ratio 1280 × 720) code stream size is about 2Mbps, 1080P (resolution ratio
1920 × 1080) code stream size be about 4~8Mbps.
Center service platform (administrative center) bandwidth calculation mainly has two parts, the video that a part is uploaded for headend equipment
Stream, service platform is to client (such as PC, notebook, smart mobile phone, wireless aps, numeral electricity in Fig. 2 centered on another part
Depending on, emergent broadcast etc.) video flowing of distribution.
For monitoring network, it is required for the service quality rating of transmission network, for example:The network delay upper limit should be less than
400ms;The delay variation upper limit should be less than 50ms;The packet loss upper limit should be less than 1 × 10-3。
In a kind of possible implementation, the center subsystem includes that storage part, video decoding spell control portion, big screen display
Show portion, management platform and remote control portion.
In a kind of possible implementation, the storage part includes centre grade video network storage device, i.e. CVR, institute
CVR is stated to be stored and backed up for hydrographic information data, video and the image to receiving.
In a kind of possible implementation, the management platform includes intelligent amended record equipment, the intelligent amended record equipment
It is connected with the CVR.
In a kind of possible implementation, control portion is spelled in the video decoding includes Video Decoder, the video decoding
Device passes through DVI (Digital Visual Interface, digital visual interface), HDMI (High Definition
Multimedia Interface, HDMI) or VGA (Video Graphics Array, video and graphic battle array
Row) the interface connection large-size screen monitors display part.
In a kind of possible implementation, the remote control portion and the robot radar ripple tachymeter and the shooting
Machine is communicated, for carrying out remote control to the robot radar ripple tachymeter and video camera.
In the present embodiment, a kind of example of Center is as follows:
Surveillance center's construction content can specifically include that control portion is spelled in power & environment supervision part, video storage part, video decoding
Point, large-size screen monitors display portion, platform management part, remote control part etc..
As shown in figure 5, being the system construction drawing of Surveillance center.Surveillance center is the core of whole video monitoring system, can
To realize the convergence of video image resource, and video image resource is managed collectively and is dispatched.Wherein, NVR (Network
Video Recorder, network hard disk video recorder) realize the storage of video image resource and call, and mould is backed up by N+1
Formula, it is ensured that video recording resource it is reliable and stable, can be including work NVR, backup NVR etc..Work NVR, backup NVR can be by connecing
Enter interchanger 56 and access core switch 55.The various video cameras that head end video is accessed can also be accessed by access switch 56
Core switch 55.Core switch 55 can also be interacted with client 57.Video synthesis platform 51 can complete video decoding
The splicing control of upper wall and image.Video synthesis platform 51 is entered in hardware view support and management platform by keyboard of network 52
Row video switches and controls, and excellent representing is carried out to HD video by the large-screen display 53 of high definition, it is also possible to led in display
Shown in machine 54.Wherein keyboard of network 52 can access video synthesis platform 51 by core switch 55.
As shown in fig. 6, the structural representation to store part.Center Streaming Media can use direct write storage scheme, scheme
Support head end encoder (being for example arranged in video synthesis platform 51) Video data with Streaming Media (GB or RTSP (Real
Time Streaming Protocol), RFC2326, the standard Streaming transfer protocol of real time streaming transport protocol) write direct
Storage system.
The design Storage of network high-definition video monitoring system can directly deposit technology and CVR videos prison using advanced video flowing
Control special purpose memory devices, for the monitor in real time video of storage management front end monitoring camera.
The design Storage of network high-definition video monitoring system directly deposits technology using advanced video flowing and CVR video monitorings are special
With storage device, for the monitor in real time video of storage management front end monitoring camera.The CCTV camera that head end video is accessed
Can be including such as high-definition network gunlock, high-definition network ball machine, high-definition network hemisphere, high-definition network all-in-one etc..Video camera institute
The video or image of collection can upload to preservation in CVR by access switch, core switch etc..Can also directly on
Video synthesis platform is passed to, is shown by large-screen display.Video or image in CVR, can also be issued to client.
As shown in fig. 7, being the schematic diagram of data backup, CVR can take front end (such as network shooting by the network switch
Machine) all the way stream realize multiple data back up, without platform participate in, save the network bandwidth and Streaming Media load, Backup Data preserve
In the machine and other storage devices, strengthen the security of data.
As shown in figure 8, being the schematic diagram of intelligent amended record (ANR).In front end and the net of data center's (i.e. center subsystem)
When network is abnormal, headend equipment starts records a video and preserves on the local storage device.After network recovery, can video recording from local
The CVR that storage device passes back to center automatically is stored, so as to ensure the integrality of data.
Further, video synthesis platform can support network code video input, VGA signal inputs, and character matrix is handed over
Change and exported with network IP matrix switch.Support that the output of DVI/HDMI/VGA interfaces, whole machine are maximum and support 256 road D1/128 roads
720P/64 roads 1080P decoding outputs.Additionally, video synthesis platform can support real-time video, history playing back videos, video solution
Wall on code, supports wall cradle head control function on dynamic decoder, supports many picture segmentations.Modulus hybrid matrix is supported to access, open a window
Control function is spelled in roaming etc..Video Decoder, the data for decoding are by output to display part.
In a kind of possible implementation, hydrology multi-antenna can use modularized design, deployment side
Just, it is easy to operate, also further customized development can be done according to the requirement of industry self-management and monitoring present situation.
For example, the general frame of hydrology multi-antenna be based primarily upon " high cohesion, loose coupling " design principle and
The thought of top-level moduleization design, using SOA (Service-Oriented Architecture, service-oriented system knot
Structure) framework, the unified Service Management of platform offer.Each application or subsystem, and functional module service end all with independence
Method of service is provided and is registered to platform, possesses good retractility and service expansion capability, to ensure that system meets information technology
The trend of development and the need for adapting to following application dynamic update.
The platform of hydrology multi-antenna can be comprising access service, treatment service, Video Applications, profession
Whole serviceizations etc..Platform can be comprising hydrology integrated information system, system for managing video, television consultation system etc..Wherein, depending on
Frequency management system can provide conventional Video Applications function, and hydrology integrated information system, television consultation system are regarded based on basis
The more rich more fully service application of frequency application function.
Specifically, system for managing video can independently build, for example, by ByteRivers integrated platforms with subsystem
Mode integration realization Union user management, resource data is shared, service interface interaction.ByteRivers is relied between each subsystem
The public service of integrated platform and system integration middleware form the ecological relationship of high cohesion loose coupling.Complete video traffic
Service interface, is easy to Video Applications to be adjusted flexibly and the customization of distinctive application self-developing.Primary access ByteRivers, can solve
Certainly public service and platform integrated functionality, rely on integrated platform quickly to realize more wider array of service sub-systems and primary subsystem
The integrating of system, can efficiently activate business.
System supports mainstream operation system, Web middlewares, database product and other third party's standard intermediate products
Exploitation and running environment, possess very strong portability.
In the utility model, visualization hydrology multi-antenna be based on OTN backbone networks, by video acquisition,
Hydrological Data Acquisition has carried out effective fusion, treatment, realizes the visual long-range monitoring of Hydrologic monitoring station with control.System
The system platform network architecture of hydrologic monitoring system is employed, existing resource is maximally utilized, makes the function of hydrology business platform
Extended.
Hydrological information collection is the basis of hydrology vocational work, and the construction for visualizing hydrology multi-antenna is improved
Hydrological information collection, transmission automatization level, to realize that hydrographic features monitoring stored digital, automatic transmission and treatment are served
Key effect.The system is equipped with quick positioning flow measurement advanced technology and carries out the monitoring sides such as water level, flow velocity using non-contact technology
Formula, forms many means, the flow monitoring system of multi-method, has reformed hydrologic survey mode, improves emergency monitoring ability, is real
Now technical support is provided in the management mode for surveying, patrolling survey, survey and hydrologic survey are combined.
Visualization hydrology multi-antenna served for hydrlolgic work prevent and reduce natural disasters, water resources development and utilization, water
Environment and ecological protection provide technology platform, improve hydrology integrity service ability.
The above, specific embodiment only of the present utility model, but protection domain of the present utility model do not limit to
In this, any one skilled in the art can readily occur in change in the technical scope that the utility model is disclosed
Or replace, should all cover within protection domain of the present utility model.Therefore, protection domain of the present utility model should be with the power
The protection domain that profit is required is defined.
Claims (10)
1. a kind of hydrology multi-antenna, it is characterised in that including:
Front end monitoring subsystem, it includes each monitoring device being arranged in Hydrologic monitoring station, and each monitoring device is included certainly
At least one in dynamic radar wave tachymeter, robot radar ripple water-level gauge and video camera;
Transmission subsystem, is connected with the front end monitoring subsystem, and the transmission subsystem includes optical transfer network OTN backbone networks,
The OTN backbone networks are used in the hydrographic information data of the Hydrologic monitoring station acquired in the monitoring device, video and image
At least one transmit to center subsystem;
The center subsystem, is connected with the transmission subsystem, for receiving, storing and shows the water of the Hydrologic monitoring station
At least one in literary information data, video and image.
2. system according to claim 1, it is characterised in that the robot radar ripple tachymeter is suspended on measured medium
On the cableway of side.
3. system according to claim 1, it is characterised in that the robot radar ripple water-level gauge include probe, emitter,
Transmitting antenna, receiver, reception antenna, processor and display;
Wherein, the emitter, the receiver, the processor and the display are integrated in cabinet, the transmitting day
Line is connected with the emitter, and the reception antenna is connected with the receiver, the transmitting antenna and the reception antenna from
The cabinet top is exposed, and the cabinet is installed in vertical rod, and the probe is installed on from the vertical rod to measured medium surface
On the cross bar of extension.
4. system according to claim 1, it is characterised in that the front end monitoring subsystem also includes:
Uninterrupted power source, for providing back-up source for each monitoring device.
5. system according to claim 1, it is characterised in that the front end monitoring subsystem also includes and the OTN bones
The network equipment of dry net connection, lightning protection device is provided with the network equipment.
6. system according to any one of claim 1 to 5, it is characterised in that the center subsystem include storage part,
Control portion, large-size screen monitors display part, management platform and remote control portion are spelled in video decoding.
7. system according to claim 6, it is characterised in that the storage part sets including centre grade video network storage
Standby, i.e. CVR, the CVR are used to that the hydrographic information data, video and the image that receive to be stored and backed up.
8. system according to claim 7, it is characterised in that the management platform includes intelligent amended record equipment, the intelligence
Energy amended record equipment is connected with the CVR.
9. system according to claim 6, it is characterised in that control portion is spelled in the video decoding includes Video Decoder, institute
State Video Decoder and the large-size screen monitors display part is connected by DVI, HDMI or USB interface.
10. system according to claim 6, it is characterised in that tested the speed with the robot radar ripple in the remote control portion
Instrument and the video camera are communicated, for carrying out remote control to the robot radar ripple tachymeter and video camera.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201621310954.3U CN206212180U (en) | 2016-12-01 | 2016-12-01 | Hydrology multi-antenna |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
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CN201621310954.3U CN206212180U (en) | 2016-12-01 | 2016-12-01 | Hydrology multi-antenna |
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Cited By (8)
Publication number | Priority date | Publication date | Assignee | Title |
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CN107421510A (en) * | 2017-08-28 | 2017-12-01 | 爱易成技术(天津)有限公司 | A kind of hydrologic monitoring device and method |
CN108645483A (en) * | 2018-04-03 | 2018-10-12 | 芜湖航飞科技股份有限公司 | Radar level gauge system |
CN109297542A (en) * | 2018-11-15 | 2019-02-01 | 长江水利委员会水文局长江中游水文水资源勘测局 | Hydrometric cableway remote online control system |
CN109660440A (en) * | 2018-12-19 | 2019-04-19 | 中国电子科技集团公司第三十八研究所 | A kind of aerostatics informationization remote support system |
CN110531684A (en) * | 2019-09-24 | 2019-12-03 | 苏州南师大科技园投资管理有限公司 | A kind of remote hydrographic monitoring system |
CN111829616A (en) * | 2020-06-24 | 2020-10-27 | 武汉世纪水元科技股份有限公司 | Remote water level identification RTU |
CN112134636A (en) * | 2020-09-18 | 2020-12-25 | 中国科学院空天信息创新研究院 | Remote centralized monitoring system and method for remote sensing satellite ground station network |
EP3746752B1 (en) * | 2018-02-02 | 2022-03-23 | Endress+Hauser SE+Co. KG | Fill level measuring device |
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2016
- 2016-12-01 CN CN201621310954.3U patent/CN206212180U/en not_active Expired - Fee Related
Cited By (8)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN107421510A (en) * | 2017-08-28 | 2017-12-01 | 爱易成技术(天津)有限公司 | A kind of hydrologic monitoring device and method |
EP3746752B1 (en) * | 2018-02-02 | 2022-03-23 | Endress+Hauser SE+Co. KG | Fill level measuring device |
CN108645483A (en) * | 2018-04-03 | 2018-10-12 | 芜湖航飞科技股份有限公司 | Radar level gauge system |
CN109297542A (en) * | 2018-11-15 | 2019-02-01 | 长江水利委员会水文局长江中游水文水资源勘测局 | Hydrometric cableway remote online control system |
CN109660440A (en) * | 2018-12-19 | 2019-04-19 | 中国电子科技集团公司第三十八研究所 | A kind of aerostatics informationization remote support system |
CN110531684A (en) * | 2019-09-24 | 2019-12-03 | 苏州南师大科技园投资管理有限公司 | A kind of remote hydrographic monitoring system |
CN111829616A (en) * | 2020-06-24 | 2020-10-27 | 武汉世纪水元科技股份有限公司 | Remote water level identification RTU |
CN112134636A (en) * | 2020-09-18 | 2020-12-25 | 中国科学院空天信息创新研究院 | Remote centralized monitoring system and method for remote sensing satellite ground station network |
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