CN111741045A - Energy internet scheduling method for green data center - Google Patents
Energy internet scheduling method for green data center Download PDFInfo
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- CN111741045A CN111741045A CN201910971517.8A CN201910971517A CN111741045A CN 111741045 A CN111741045 A CN 111741045A CN 201910971517 A CN201910971517 A CN 201910971517A CN 111741045 A CN111741045 A CN 111741045A
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L67/00—Network arrangements or protocols for supporting network services or applications
- H04L67/01—Protocols
- H04L67/12—Protocols specially adapted for proprietary or special-purpose networking environments, e.g. medical networks, sensor networks, networks in vehicles or remote metering networks
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L67/00—Network arrangements or protocols for supporting network services or applications
- H04L67/01—Protocols
- H04L67/10—Protocols in which an application is distributed across nodes in the network
- H04L67/1097—Protocols in which an application is distributed across nodes in the network for distributed storage of data in networks, e.g. transport arrangements for network file system [NFS], storage area networks [SAN] or network attached storage [NAS]
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04N—PICTORIAL COMMUNICATION, e.g. TELEVISION
- H04N7/00—Television systems
- H04N7/18—Closed-circuit television [CCTV] systems, i.e. systems in which the video signal is not broadcast
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Abstract
The invention discloses an energy internet dispatching method facing a green data center, which comprises a commanding and dispatching system, a terminal display, a wireless communication system and an image and voice transmission system, the command scheduling system consists of a pan-tilt control module, a real-time monitoring module and a system management module, the invention transmits and stores information by adopting a cloud service platform, then, the condition needing to be scheduled is transmitted by utilizing real-time monitoring, which is beneficial to a monitoring platform to better know the condition in all directions, thus better scheduling can be carried out, thereby avoiding the phenomenon of inaccurate scheduling caused by incomplete information receiving, greatly improving the working efficiency and the working accuracy to ensure the consistency of data, and all the nodes of the data are communicated with each other, so that the data transmission is kept secret more and is not lost.
Description
Technical Field
The invention belongs to the field of relevant technologies, and particularly relates to an energy internet scheduling method for a green data center.
Background
The development of new energy Internet is a new energy revolution. The integration of the internet and each industry is a brand new opportunity of the development of the industry, plays a vital role in improving the development quality and the economic benefit of the industry, energy is the most important basic industry, and through the reconstruction and the transformation of new internet technologies, the energy industry, particularly the new energy industry, can develop strong power and create immeasurable new value, and the new energy internet can be a new wealth gold mine in the 21 st century.
The prior energy internet scheduling method has the following problems: the conventional energy Internet scheduling method cannot perform scheduling well according to the actual situation when performing scheduling, the received actual situation is not complete, and the obtained data are relatively independent and can not be unified, so that the problem of a phenomenon of mutual contradiction can be caused when performing scheduling.
Disclosure of Invention
The invention aims to provide an energy internet scheduling method facing a green data center, and aims to solve the problem that the existing energy internet scheduling method proposed in the background art cannot perform scheduling well according to the actual situation when performing scheduling.
In order to achieve the purpose, the invention provides the following technical scheme:
a green data center-oriented energy internet scheduling method comprises a command scheduling system, a terminal display, a wireless communication system, an image and voice transmission system, wherein the command scheduling system is composed of a holder control module, a real-time monitoring module and a system management module, the holder control module in the command scheduling system realizes holder control through a visual operation window, a video monitoring probe is adjusted, and the functions of adjusting direction, focal length, resolution ratio and the like are realized;
the terminal display consists of a control platform and a display screen, the control platform in the terminal display has the function of effectively selecting information through manual operation, and the display screen in the terminal display has the function of playing a video to be watched;
the wireless communication system consists of a sending equipment module, a receiving equipment module and a transmission media module, wherein the sending equipment module in the wireless communication system has the function of sending information, the receiving equipment in the wireless communication system has the function of receiving information, and the transmission media module in the wireless communication system has the functions of transmitting and sending media;
the image and voice transmission system is composed of a transmitter end equipment module and a receiver end equipment module, the transmitter end equipment module in the image and voice transmission system has the function of sending images and voices, and the receiver end equipment module in the image and voice transmission system has the function of receiving images and voices.
The energy internet scheduling method comprises the following steps:
the method comprises the following steps: building an energy internet big data cloud service platform;
step two: initializing energy and information network states;
step three: setting a node controller to complete energy scheduling in the energy microgrid;
step four: determining a source host IP address and a destination host IP address which need to be subjected to energy transmission according to the energy condition of each microgrid by an energy internet control node;
step five: energy load node data acquisition and cloud storage in the energy internet and energy load node micro-metarization;
step six: and reporting the root controller through the node controllers, finishing energy scheduling across the energy microgrid, wherein each node controller comprises a node communication controller and a node energy controller, and each node communication controller comprises a node SDN controller.
The use requirements of the real-time monitoring module are as follows:
the control part of the video monitoring comprehensive application platform, such as a control console, is responsible for controlling the content shared by all users and related operations, and then the control and interaction of the content displayed by the video monitoring comprehensive application platform can be realized through a system management module;
secondly, on the video monitoring, storing and sharing server, the unified centralized management function of the whole video monitoring integrated application platform is realized, and the specific functions comprise: controlling various user roles and authorities in the video surveillance comprehensive application platform to manage; data linkage between different screen display contents; managing all log records of the whole system, including all log-in/log-out records of related software in the system, issuing records of display contents of a display screen and the like;
and thirdly, accessing the video signal of the appointed video monitoring point into a command system to realize real-time monitoring. The video data in different compression formats can be decompressed and played on a large screen, a monitor and a PC terminal, and a user with authority is allowed to take video snapshot of the video being played and store the video to the local;
and fourthly, realizing cloud deck control through a visual operation window, adjusting the video monitoring probe, and adjusting the direction, the focal length, the resolution ratio and the like. The received video image can be enlarged or reduced.
The use requirements of the transmitter end equipment module and the receiver end equipment module in the image and voice transmission system are as follows:
the method comprises the following steps: checking whether the relevant accessories of the transmitter side equipment are complete;
firstly, connecting transmitting terminal equipment;
secondly, connecting an antenna;
thirdly, connecting a 12V power supply;
fourthly, connecting an audio and video wire and turning on a power supply of the camera;
fifthly, turning on a power switch and starting up;
sixthly, after the mobile phone is started for twelve seconds, the indicator light of the transmitter is turned on, the transmitter completes initialization, and the mobile phone starts to work.
Step two: checking whether the relevant accessories of the receiving end equipment are complete;
firstly, connecting receiving end equipment;
secondly, connecting an antenna;
thirdly, connecting a 220V power supply;
fourthly, connecting the audio and video cable to a monitor;
fifthly, turning on a power switch and starting up;
and sixthly, indicating that the receiver works normally after the startup picture appears.
The notice of the transmitter-side equipment module and the receiver-side equipment module in the image and voice transmission system is as follows:
firstly, a starting sequence: generally, a receiver is started first, and then a transmitter system is developed to be more reliable;
secondly, before the transmitter is started, the antenna is confirmed to be connected; the camera is turned on first, so that the system works more reliably;
thirdly, when the image of the receiver is abnormal;
(1) checking whether the receiver has a starting-up picture or not, and if not, checking whether the contact of a video connector connected with the monitor is good or not;
(2) and after the starting-up picture appears, checking whether to display: if the signal exists, the communication channel works normally, and whether the contact of a video connector connected with the transmitter and the camera is good is checked;
(3) and restarting the transmitter.
The information forwarding nodes of each energy microgrid are mutually communicated and are commonly connected with one information aggregation forwarding node, the N information aggregation forwarding nodes are commonly connected with the data transmission network, and the information forwarding nodes contained in all the energy microgrids are mutually communicated.
Compared with the prior art, the invention provides an energy internet scheduling method for a green data center, which has the following beneficial effects:
according to the invention, the cloud service platform is adopted to transmit and store information, and then the condition needing scheduling is transmitted by utilizing real-time monitoring, so that the monitoring platform can better know the condition in all directions, better scheduling can be realized, the phenomenon of inaccurate scheduling caused by incomplete information receiving is avoided, the working efficiency and the working accuracy are greatly improved, the data consistency is ensured, and the data transmission is more confidential and cannot be lost due to the fact that all nodes are communicated with one another.
Detailed Description
The invention provides a technical scheme that:
a green data center-oriented energy internet scheduling method comprises a command scheduling system, a terminal display, a wireless communication system and an image and voice transmission system, wherein the command scheduling system consists of a holder control module, a real-time monitoring module and a system management module, the holder control module in the command scheduling system realizes holder control through a visual operation window, a video monitoring probe is adjusted, and the functions of adjusting direction, focal length, resolution ratio and the like are realized;
the terminal display consists of a control platform and a display screen, wherein the control platform in the terminal display has the function of effectively selecting information by manual operation, and the display screen in the terminal display has the function of playing a video to be watched;
the wireless communication system consists of a sending equipment module, a receiving equipment module and a transmission media module, wherein the sending equipment module in the wireless communication system has the function of sending information, the receiving equipment in the wireless communication system has the function of receiving information, and the transmission media module in the wireless communication system has the functions of transmitting and sending media;
the image and voice transmission system is composed of a transmitter end equipment module and a receiver end equipment module, wherein the transmitter end equipment module in the image and voice transmission system has the function of transmitting images and voices, and the receiver end equipment module in the image and voice transmission system has the function of receiving images and voices.
The energy internet scheduling method comprises the following steps:
the method comprises the following steps: building an energy internet big data cloud service platform;
step two: initializing energy and information network states;
step three: setting a node controller to complete energy scheduling in the energy microgrid;
step four: determining a source host IP address and a destination host IP address which need to be subjected to energy transmission according to the energy condition of each microgrid by an energy internet control node;
step five: energy load node data acquisition and cloud storage in the energy internet and energy load node micro-metarization;
step six: and reporting the root controller through the node controllers, finishing energy scheduling across the energy microgrid, wherein each node controller comprises a node communication controller and a node energy controller, and each node communication controller comprises a node SDN controller.
The use requirements of the real-time monitoring module are as follows:
the control part of the video monitoring comprehensive application platform, such as a control console, is responsible for controlling the content shared by all users and related operations, and then the control and interaction of the content displayed by the video monitoring comprehensive application platform can be realized through a system management module;
secondly, on the video monitoring, storing and sharing server, the unified centralized management function of the whole video monitoring integrated application platform is realized, and the specific functions comprise: controlling various user roles and authorities in the video surveillance comprehensive application platform to manage; data linkage between different screen display contents; managing all log records of the whole system, including all log-in/log-out records of related software in the system, issuing records of display contents of a display screen and the like;
and thirdly, accessing the video signal of the appointed video monitoring point into a command system to realize real-time monitoring. The video data in different compression formats can be decompressed and played on a large screen, a monitor and a PC terminal, and a user with authority is allowed to take video snapshot of the video being played and store the video to the local;
and fourthly, realizing cloud deck control through a visual operation window, adjusting the video monitoring probe, and adjusting the direction, the focal length, the resolution ratio and the like. The received video image can be enlarged or reduced.
The use requirements of the transmitter-end equipment module and the receiver-end equipment module in the image and voice transmission system are as follows:
the method comprises the following steps: checking whether the relevant accessories of the transmitter side equipment are complete;
firstly, connecting transmitting terminal equipment;
secondly, connecting an antenna;
thirdly, connecting a 12V power supply;
fourthly, connecting an audio and video wire and turning on a power supply of the camera;
fifthly, turning on a power switch and starting up;
sixthly, after the mobile phone is started for twelve seconds, the indicator light of the transmitter is turned on, the transmitter completes initialization, and the mobile phone starts to work.
Step two: checking whether the relevant accessories of the receiving end equipment are complete;
firstly, connecting receiving end equipment;
secondly, connecting an antenna;
thirdly, connecting a 220V power supply;
fourthly, connecting the audio and video cable to a monitor;
fifthly, turning on a power switch and starting up;
and sixthly, indicating that the receiver works normally after the startup picture appears.
The notice of the transmitter-side equipment module and the receiver-side equipment module inside the image and voice transmission system is as follows:
firstly, a starting sequence: generally, a receiver is started first, and then a transmitter system is developed to be more reliable;
secondly, before the transmitter is started, the antenna is confirmed to be connected; the camera is turned on first, so that the system works more reliably;
thirdly, when the image of the receiver is abnormal;
(1) checking whether the receiver has a starting-up picture or not, and if not, checking whether the contact of a video connector connected with the monitor is good or not;
(2) and after the starting-up picture appears, checking whether to display: if the signal exists, the communication channel works normally, and whether the contact of a video connector connected with the transmitter and the camera is good is checked;
(3) and restarting the transmitter.
The information forwarding nodes of each energy microgrid are mutually communicated and are commonly connected with one information aggregation forwarding node, the N information aggregation forwarding nodes are commonly connected with the data transmission network, and the information forwarding nodes contained in all the energy microgrids are mutually communicated.
The working principle and the using process of the invention are as follows:
when energy is scheduled, firstly, an energy internet big data cloud service platform is built, then, the states of energy and information networks are initialized, then, energy scheduling is completed in the energy microgrid through setting a node controller, then, according to the energy condition of each microgrid, a source host IP address and a destination host IP address which need energy transmission are determined by an energy internet control node, energy load node data acquisition and cloud storage and energy load node micro-metarization in the energy internet are carried out, meanwhile, a root controller is reported through the node controller, energy scheduling is completed across the energy microgrid, each node controller comprises a node communication controller and a node energy controller, each node communication controller comprises a node SDN controller, information forwarding nodes of each energy microgrid are mutually communicated and are jointly connected with an information aggregation forwarding node, the N information aggregation forwarding nodes are connected with the data transmission network together, and the information forwarding nodes contained in all the energy micro-networks are mutually communicated.
Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.
Claims (6)
1. A green data center-oriented energy Internet scheduling method comprises a command scheduling system, a terminal display, a wireless communication system and an image and voice transmission system, and is characterized in that: the command and dispatch system is composed of a holder control module, a real-time monitoring module and a system management module, wherein the holder control module in the command and dispatch system realizes holder control through a visual operation window, adjusts a video monitoring probe and can adjust the functions of direction, focal length, resolution ratio and the like;
the terminal display consists of a control platform and a display screen, the control platform in the terminal display has the function of effectively selecting information through manual operation, and the display screen in the terminal display has the function of playing a video to be watched;
the wireless communication system consists of a sending equipment module, a receiving equipment module and a transmission media module, wherein the sending equipment module in the wireless communication system has the function of sending information, the receiving equipment in the wireless communication system has the function of receiving information, and the transmission media module in the wireless communication system has the functions of transmitting and sending media;
the image and voice transmission system is composed of a transmitter end equipment module and a receiver end equipment module, the transmitter end equipment module in the image and voice transmission system has the function of sending images and voices, and the receiver end equipment module in the image and voice transmission system has the function of receiving images and voices.
2. The green data center-oriented energy internet scheduling method according to claim 1, wherein the green data center-oriented energy internet scheduling method comprises the following steps: the energy internet scheduling method comprises the following steps:
the method comprises the following steps: building an energy internet big data cloud service platform;
step two: initializing energy and information network states;
step three: setting a node controller to complete energy scheduling in the energy microgrid;
step four: determining a source host IP address and a destination host IP address which need to be subjected to energy transmission according to the energy condition of each microgrid by an energy internet control node;
step five: energy load node data acquisition and cloud storage in the energy internet and energy load node micro-metarization;
step six: and reporting the root controller through the node controllers, finishing energy scheduling across the energy microgrid, wherein each node controller comprises a node communication controller and a node energy controller, and each node communication controller comprises a node SDN controller.
3. The green data center-oriented energy internet scheduling method according to claim 1, wherein the green data center-oriented energy internet scheduling method comprises the following steps: the use requirements of the real-time monitoring module are as follows:
the control part of the video monitoring comprehensive application platform, such as a control console, is responsible for controlling the content shared by all users and related operations, and then the control and interaction of the content displayed by the video monitoring comprehensive application platform can be realized through a system management module;
secondly, on the video monitoring, storing and sharing server, the unified centralized management function of the whole video monitoring integrated application platform is realized, and the specific functions comprise: controlling various user roles and authorities in the video surveillance comprehensive application platform to manage; data linkage between different screen display contents; managing all log records of the whole system, including all log-in/log-out records of related software in the system, issuing records of display contents of a display screen and the like;
thirdly, accessing the video signal of the appointed video monitoring point into a command system to realize real-time monitoring;
the video data in different compression formats can be decompressed and played on a large screen, a monitor and a PC terminal, and a user with authority is allowed to take video snapshot of the video being played and store the video to the local;
and fourthly, realizing cloud deck control through a visual operation window, adjusting the video monitoring probe, and adjusting the direction, the focal length, the resolution ratio and the like.
4. The received video image can be amplified, reduced and the like;
the green data center-oriented energy internet scheduling method according to claim 1, wherein the green data center-oriented energy internet scheduling method comprises the following steps: the use requirements of the transmitter end equipment module and the receiver end equipment module in the image and voice transmission system are as follows:
the method comprises the following steps: checking whether the relevant accessories of the transmitter side equipment are complete;
firstly, connecting transmitting terminal equipment;
secondly, connecting an antenna;
thirdly, connecting a 12V power supply;
fourthly, connecting an audio and video wire and turning on a power supply of the camera;
fifthly, turning on a power switch and starting up;
sixthly, starting for twelve seconds, lighting an indicator lamp of the transmitter, finishing initialization of the transmitter and starting to work;
step two: checking whether the relevant accessories of the receiving end equipment are complete;
firstly, connecting receiving end equipment;
secondly, connecting an antenna;
thirdly, connecting a 220V power supply;
fourthly, connecting the audio and video cable to a monitor;
fifthly, turning on a power switch and starting up;
and sixthly, indicating that the receiver works normally after the startup picture appears.
5. The green data center-oriented energy internet scheduling method according to claim 1, wherein the green data center-oriented energy internet scheduling method comprises the following steps: the notice of the transmitter-side equipment module and the receiver-side equipment module in the image and voice transmission system is as follows:
firstly, a starting sequence: generally, a receiver is started first, and then a transmitter system is developed to be more reliable;
secondly, before the transmitter is started, the antenna is confirmed to be connected; the camera is turned on first, so that the system works more reliably;
thirdly, when the image of the receiver is abnormal;
(1) checking whether the receiver has a starting-up picture or not, and if not, checking whether the contact of a video connector connected with the monitor is good or not;
(2) and after the starting-up picture appears, checking whether to display: if the signal exists, the communication channel works normally, and whether the contact of a video connector connected with the transmitter and the camera is good is checked;
(3) and restarting the transmitter.
6. The green data center-oriented energy internet scheduling method according to claim 1, wherein the green data center-oriented energy internet scheduling method comprises the following steps: the information forwarding nodes of each energy microgrid are mutually communicated and are commonly connected with one information aggregation forwarding node, the N information aggregation forwarding nodes are commonly connected with the data transmission network, and the information forwarding nodes contained in all the energy microgrids are mutually communicated.
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