CN204231028U - Intelligent grid data dispatching remote online diagnosis and analysis device - Google Patents

Abstract

The utility model relates to a telecontrol system of an electric power system, in particular to a remote on-line diagnosis and analysis device for dispatching data of a smart grid. The utility model solves the problems that the existing electric power system telecontrol system lacks a reasonable network topology structure and a uniform and efficient transmission medium. Smart grid dispatching data remote online diagnosis and analysis device, including master RTU, slave RTU, substation protection device, substation measurement and control device, first front server, second front server, master server, backup server, monitoring acquisition server, storage analysis server , monitoring workstation, maintenance workstation, wireless universal serial bus, PROFIBUS bus, RS485 communication cable; N slave RTUs, master RTU, and wireless universal serial bus together form a bus topology. The utility model is suitable for electric power systems.

Description

Smart grid dispatching data remote online diagnosis and analysis device

technical field

The utility model relates to a telecontrol system of an electric power system, in particular to a remote on-line diagnosis and analysis device for dispatching data of a smart grid.

Background technique

Power system telecontrol refers to the application of communication technology and computer technology to collect real-time data and information of the power system, and to monitor and control the operation of the power grid and remote power plants and substations. At present, the power system telecontrol is mainly realized by relying on the power system telecontrol system. Under the existing technical conditions, the power system telecontrol system generally has the following problems due to its own structure: First, the existing power system telecontrol system generally lacks a reasonable network topology structure, which leads to the problem of unstable data transmission , which directly affects the reliability and security of power system operation. Second, the existing power system telecontrol systems generally lack a unified and efficient transmission medium, which leads to the problems of slow data transmission speed and poor data sharing, which also affects the reliability and safety of power system operation. Based on this, it is necessary to invent a brand new power system telecontrol system to solve the problems that the existing power system telecontrol system lacks a reasonable network topology and lacks a unified and efficient transmission medium.

Contents of the invention

The utility model provides a remote online diagnosis and analysis device for dispatching data of a smart grid in order to solve the problems that the existing electric power system telecontrol system lacks a reasonable network topology structure and a unified and efficient transmission medium.

The utility model is realized by adopting the following technical scheme: a remote online diagnosis and analysis device for smart grid scheduling data, including a master RTU, a slave RTU, a substation protection device, a substation measurement and control device, a first pre-server, a second pre-server, and a main server , backup server, monitoring acquisition server, storage analysis server, monitoring workstation, maintenance workstation, wireless universal serial bus, PROFIBUS bus, RS485 communication cable; among them, the number of subordinate RTU, the number of substation protection devices, and the number of substation measurement and control devices are all The number of PROFIBUS buses is N+4; N slave RTUs and master RTUs are connected to the wireless universal serial bus, and N slave RTUs, master RTUs, and wireless universal serial buses together form a bus topology ; The i-th slave RTU, the i-th substation protection device, and the i-th substation measurement and control device are all connected to the i-th PROFIBUS bus, and the i-th slave RTU, the i-th substation protection device, the i-th substation measurement and control device, The i-th PROFIBUS bus together constitutes a bus topology; the first front-end server, the second front-end server, and the main RTU are all connected to the N+1-th PROFIBUS bus, and the first front-end server, the second front-end server, The main RTU and the N+1th PROFIBUS bus together form a bus topology; the main server, the standby server, the first front-end server, and the second front-end server are all connected to the N+2th PROFIBUS bus, and the main server, the backup The server, the first front-end server, the second front-end server, and the N+2th PROFIBUS bus together form a bus topology; the main server, the backup server, the first front-end server, and the second front-end 3-way PROFIBUS bus connection, and the main server, backup server, first front-end server, second front-end server, and N+3rd PROFIBUS bus together form a bus topology; the monitoring and acquisition server is connected to the main RTU through an RS485 communication cable ;The monitor collection server, storage analysis server, monitoring workstation, and maintenance workstation are all connected to the N+4th PROFIBUS bus, and the monitor collection server, storage analysis server, monitoring workstation, maintenance workstation, and N+4th PROFIBUS bus together constitute the bus type topology; N is a positive integer; i is a positive integer, and 1≤i≤N.

The specific working process is as follows: the i-th substation protection device sends its internal data to the i-th PROFIBUS bus in real time. The i-th substation measurement and control device sends its internal data to the i-th PROFIBUS bus in real time. The i-th slave RTU accesses the i-th PROFIBUS bus in real time and acquires data, and then sends the acquired data to the wireless universal serial bus in real time. The main RTU accesses the wireless universal serial bus and obtains data in real time, and then sends the obtained data to the N+1th PROFIBUS bus in real time. The first front-end server accesses the N+1th PROFIBUS bus in real time and acquires data, and then sends the acquired data to the N+2th PROFIBUS bus and the N+3th PROFIBUS bus in real time. The second front-end server accesses the N+1th PROFIBUS bus in real time and obtains data, and then sends the acquired data to the N+2th PROFIBUS bus and the N+3th PROFIBUS bus in real time. The main server accesses the N+2th PROFIBUS bus and the N+3rd PROFIBUS bus in real time and obtains data. The standby server accesses the N+2 PROFIBUS bus and the N+3 PROFIBUS bus in real time and acquires data. The monitoring and collection server collects the data obtained by the main RTU in real time through the RS485 communication cable, and sends the collected data to the N+4th PROFIBUS bus in real time. The storage analysis server accesses the N+4th PROFIBUS bus in real time and obtains data. The monitoring workstation accesses the N+4 PROFIBUS bus in real time and acquires data. The maintenance workstation accesses the N+4th PROFIBUS bus in real time and acquires data. Based on the above process, compared with the existing power system telecontrol system, the smart grid dispatching data remote online diagnosis and analysis device described in the utility model has the following advantages by adopting a new structure: First, the smart grid scheduling data described in the utility model has the following advantages: The remote online diagnosis and analysis device for power grid dispatching data adopts slave RTU, master RTU, and wireless universal serial bus to form a bus topology structure, and uses slave RTU, substation protection device, and substation measurement and control device to form N bus topology structures. A front-end server, the second front-end server, the main RTU, and the PROFIBUS bus form a bus topology structure, and the main server, the backup server, the first front-end server, the second front-end server, and the PROFIBUS bus form two buses. A bus-type topology structure, which uses monitoring and acquisition servers, storage and analysis servers, monitoring workstations, maintenance workstations, and PROFIBUS buses to form a bus-type topology structure. By using the bus-type topology structure, it has a simple structure, requires less transmission media, and has no central nodes. The failure of any node will not cause the entire network to be paralyzed, with the advantages of high reliability and easy expansion. It has a reasonable network topology, so its data transmission is more stable. Its two, the smart grid scheduling data remote online diagnosis and analysis device described in the utility model adopts the wireless universal serial bus, PROFIBUS bus, RS485 communication cable as the transmission medium, and on the one hand, it utilizes the high bandwidth of the wireless universal serial bus and the carrying frequency On the other hand, by using the advantages of high speed and low cost of the PROFIBUS bus, combined with the advantages of good anti-noise interference and long transmission distance of the RS485 communication cable, it has a unified and efficient transmission medium, so its Data transfer is faster and data shareability is higher. In summary, the smart grid scheduling data remote online diagnosis and analysis device described in the utility model effectively solves the problems of the lack of a reasonable network topology structure and the lack of a unified and efficient transmission medium in the existing power system telecontrol system by adopting a new structure , thus effectively ensuring the reliability and safety of the power system operation.

The utility model effectively solves the problems that the telecontrol system of the existing power system lacks a reasonable network topology structure and a unified and efficient transmission medium, and is suitable for the power system.

Description of drawings

Fig. 1 is the structural representation of the utility model.

detailed description

Smart grid dispatching data remote online diagnosis and analysis device, including master RTU, slave RTU, substation protection device, substation measurement and control device, first front server, second front server, master server, backup server, monitoring acquisition server, storage analysis server , monitoring workstation, maintenance workstation, wireless universal serial bus, PROFIBUS bus, RS485 communication cable;

Among them, the number of subordinate RTUs, the number of substation protection devices, and the number of substation measurement and control devices are all N; the number of PROFIBUS buses is N+4;

The N slave RTUs and the master RTU are all connected to the wireless universal serial bus, and the N slave RTUs, the master RTU, and the wireless universal serial bus together form a bus topology;

The i-th slave RTU, the i-th substation protection device, and the i-th substation measurement and control device are all connected to the i-th PROFIBUS bus, and the i-th slave RTU, the i-th substation protection device, the i-th substation measurement and control device, the i-th substation The i PROFIBUS buses together form a bus topology;

The first front-end server, the second front-end server, and the main RTU are all connected to the N+1th PROFIBUS bus, and the first front-end server, the second front-end server, the main RTU, and the N+1th PROFIBUS bus jointly constitute bus topology;

The main server, standby server, first front-end server, and second front-end server are all connected to the N+2th PROFIBUS bus, and the main server, backup server, first front-end server, second front-end server, N+th 2 PROFIBUS buses together form a bus topology;

The main server, standby server, first front-end server, and second front-end server are all connected to the N+3th PROFIBUS bus, and the main server, backup server, first front-end server, second front-end server, N+th 3-way PROFIBUS buses together form a bus topology;

The monitoring collection server is connected to the main RTU through the RS485 communication cable;

The monitoring acquisition server, storage analysis server, monitoring workstation, and maintenance workstation are all connected to the N+4th PROFIBUS bus, and the monitoring acquisition server, storage analysis server, monitoring workstation, maintenance workstation, and the N+4th PROFIBUS bus together form a bus type Topology;

N is a positive integer; i is a positive integer, and 1≤i≤N.

During specific implementation, the main RTU and the subordinate RTU all adopt the JY-RTU6640 type RTU; the first front-end server, the second front-end server, the main server, the backup server, the monitoring acquisition server, and the storage analysis server all adopt IBM x3650 M4 server; the monitoring workstation and maintenance workstation all adopt UltraLAB Alpha600 workstation.

Claims (2)

1. an intelligent grid data dispatching remote online diagnosis and analysis device, is characterized in that: comprise main RTU, subordinate RTU, transforming plant protecting device, transformer station measurement and control device, the first front server, the second front server, master server, standby server, monitor acquisition server, inventory analysis server, follow-up work station, maintenance work station, radio universal serial bus, PROFIBUS bus, RS485 communication cable;

Wherein, the number of subordinate RTU, the number of transforming plant protecting device, the number of transformer station measurement and control device are N number of; The number of PROFIBUS bus is N+4 road;

N number of subordinate RTU is all connected with radio universal serial bus with main RTU, and N number of subordinate RTU, main RTU, radio universal serial bus form bus type topological structure jointly;

I-th subordinate RTU, i-th transforming plant protecting device, i-th transformer station measurement and control device Jun Yu i-th road PROFIBUS bus connect, and i-th subordinate RTU, i-th transforming plant protecting device, i-th transformer station measurement and control device, the i-th road PROFIBUS bus form bus type topological structure jointly;

First front server, the second front server, main RTU are all connected with N+1 road PROFIBUS bus, and the first front server, the second front server, main RTU, N+1 road PROFIBUS bus form bus type topological structure jointly;

Master server, standby server, the first front server, the second front server are all connected with N+2 road PROFIBUS bus, and master server, standby server, the first front server, the second front server, N+2 road PROFIBUS bus form bus type topological structure jointly;

Master server, standby server, the first front server, the second front server are all connected with N+3 road PROFIBUS bus, and master server, standby server, the first front server, the second front server, N+3 road PROFIBUS bus form bus type topological structure jointly;

Monitor acquisition server to be connected with main RTU by RS485 communication cable;

Monitor acquisition server, inventory analysis server, follow-up work station, maintenance work station be all connected with N+4 road PROFIBUS bus, and monitoring acquisition server, inventory analysis server, follow-up work station, maintenance work station, N+4 road PROFIBUS bus form bus type topological structure jointly;

N is positive integer; I is positive integer, and 1≤i≤N.

2. intelligent grid data dispatching remote online diagnosis and analysis device according to claim 1, is characterized in that: described main RTU, subordinate RTU all adopt JY-RTU6640 type RTU; Described first front server, the second front server, master server, standby server, monitoring acquisition server, inventory analysis server all adopt IBM x3650 M4 type server; Described follow-up work station, maintenance work station all adopt UltraLAB Alpha600 type work station.