RU2210104C2 - Multiprocessor information-management relay protection and automatic control system - Google Patents

Abstract

FIELD: computer and relay protection engineering. SUBSTANCE: proposed system that can be used for automating acquisition of data on status of entered information, connections and switches of checked and controlled entity, automating acquisition, analysis, and storage of data on emergency processes, acquisition of diagnostics information from relay protective and automatic-control units has N processing devices, N communication centers, and microprocessor converter; each of processing devices has processing unit and two interface units; microprocessor converter has two amplifiers, microprocessor, set of OR gates, AND gate, electrical-to-optical signal converter, and optical-to-electrical signal converter. EFFECT: enlarged functional capabilities. 1 cl, 5 dwg

Description

 The invention relates to computer technology and relay protection technology and is intended to automate the process of collecting information about the state of inputs, connections and switches of an object of control and management, processing this information and transmitting it to operational personnel.

 Known system for connecting multiple devices [A.S. G 06 F 15/16, 337902, B.I. 34, 1987], containing the main computing device, slave computing devices, each of which contains a central data processing device with an input / output selector circuit and a storage device that is equipped with input and output batteries, is used to solve various problems of information processing control but has limited functionality.

 Known multiprocessor computing system [A.C. G 06 F 15/16, 820391, B. I. 21, 1993], containing N processing devices. M input-output devices and a storage device, the processing device comprising a computing unit, first and second shutdown units, a pulse shaper, a control trigger, and an element And are also used to solve various problems of managing information processing processes, but have limited functionality.

 The closest technical solution is a microprocessor-based computing system [A. C. G 06 F 15/16, 1805477, B.I. 12, 1993], containing N processing devices and N communication nodes, each processing device comprising a processing unit and two interface nodes with a trunk, each communication node containing nine AND elements, four OR elements, and a trigger. The prototype has ample reconfiguration capabilities, but has limited functionality for managing various information processing processes.

 The purpose of the invention is the expansion of the system’s functionality by introducing automation functions for the process of collecting information about the state of inputs, connections and switches, an object for monitoring and control, automation of the collection, analysis and storage of information about emergency processes with the possibility of remote configuration and control of settings of microprocessor relay protection devices, and also remote collection of diagnostic information from digital relay protection and automation units.

 This goal is achieved by the fact that in a known system containing N processing devices and N communication nodes, each processing device comprising a processing unit and two interface nodes with a trunk, and the output of the b-th communication node (where b = 1 ... N- 1) connected to the input of the (b + 1) -th communication node, a microprocessor converter is introduced, the information inputs and outputs of the first group of each N-th processing device connected to the information inputs and outputs of the corresponding N-th communication node, information inputs and outputs of the second groups of each Nth mustache processing triples are the first group of inputs and outputs of the system, the second group of inputs and outputs of which are the input-output groups of N processing units, the first and second groups of inputs of which are the group of inputs of the system, the output of the Nth communication node is connected to the input of the microprocessor converter, the output of which is connected to the input of the first communication node, the group of inputs and outputs of the microprocessor converter is the third group of inputs and outputs of the system, and the microprocessor converter consists of two amplifiers, a cropping unit, a set of OR elements, an And element, an electrical to optical signal converter, and an optical to electric signal converter, the input-output group of the microprocessor converter being the input of the first amplifier and the output of the second amplifier, the input of which is connected to the output of the element And, the first input of which is connected to the third input of the set of elements OR and with the first output of the microprocessor, the input of which is connected to the output of the first amplifier, the second output of the microprocessor is connected to the first input a set of OR elements, the second input of which is connected to the second input of the And element and with the output of the optical signal to electric converter, the input of which is the input of a microprocessor converter, the output of which is the output of the electric signal to optical converter, the input of which is connected to the output of the set of OR elements.

 In FIG. Figure 1 shows the structural diagram of one information loop (multiprocessor system) of the information management complex.

 Figure 2 is an example implementation of a processing device.

 Figure 3 is an example implementation of a microprocessor converter.

 Figure 4 is an example implementation of a communication node.

 Figure 5 is an example implementation of an information management complex.

Figure 1 marked:
1 - industrial powerful computer;
2 - microprocessor converter;
3 ₁ ... 3 _N - communication nodes;
4 ₁ , ... 4 _N - interface nodes with the trunk (RS-485 interface);
5 ₁ ... 5 _N - processing units;
6 ₁ ... 6 _N - interface nodes with the trunk (RS-232 interface);
7 ₁ ... 7 _N - processing devices;
8 - a personal computer, for example, "NOTEBOOK" or similar;
9 - multiprocessor system.

Figure 2 marked:
10 - block galvanic isolation and preliminary scaling of signals in the form of current;
11 - block galvanic isolation and preliminary scaling of signals in the form of voltage;
12 - shaper of signals of control and diagnostics;
13 - block frequency filters;
14 - analog-to-digital Converter;
15 - microprocessor control system of output relays and alarm in accordance with protection algorithms.

In figure 3 and 4 are indicated:
16 - amplifier, for example SP232EEP company "SIPEX" or similar;
17 - a microprocessor, for example PIC12C508A - 04I / P company "MICROCHIP" or similar;
18 is a set of OR elements, for example, MC74AC00N of the company "MOTOROLA" or similar;
19 is a converter of electrical signals into optical ones, for example, HFBR-1414M manufactured by HEWLETT PACKARD or the like;
20 - a converter of optical signals into electrical ones, for example, AFPU or similar ;.

21 - And element, for example 74AC00 or similar;
Figure 5 marked:
22 ₁ - 22 _N - automated workstations of control operators;
23 - inter-channel switch, for example ETHERNET;
24 - inter-channel switch, for example SWITCH;
25 ₁ - 25 _N - servers, for example, Primary Domain Controller, Back Domain Controller; SCADA etc.

 Processing unit 5 can be implemented in accordance with the application for the grant of a patent of the Russian Federation for the invention N 02 N 7/26, 2000102777/09 (002690) dated 03.02.2000, having a decision on the grant of a patent for the invention of 05.25.2001. or [N.N. Chernobrovov, V.A. Semenov "Relay protection of energy systems", 1998, p. 778, fig. 22.4]. The RS-232 and RS-485 channel drivers are located in the microprocessor system and are not shown in the diagram (see page 781). Detailed information on the operation of the processing unit and the microprocessor system is given in the application and the literature on pages 778-783.

The multiprocessor information and control system of relay protection and automation contains N processing devices 7 ₁ ... 7 _N , N communication nodes 3 ₁ ... 3 _N and a microprocessor converter 2, and each processing device 7 contains a processing unit 5 and two interface nodes with highway 4 and 6, and the output of the b-th communication node 3 (where b = 1 ... N-1) is connected to the input of the (b + 1) -th communication node 3, information inputs and outputs of the first group of each N-th device processing 7 are connected to the information inputs and outputs of the corresponding N-th communication node 3, the information inputs The second group of each Nth processing device 7 is the first group of inputs and outputs of the system, the second group of inputs and outputs of which are the groups of inputs and outputs of N processing units, the first and second groups of inputs of which are the group of inputs of the system, the output of the last communication node 3 _{N is} connected to the input of the microprocessor converter 2, the output of which is connected to the input of the first communication node 3 ₁ , the group of inputs / outputs of the microprocessor converter is the third group of inputs / outputs of the system, microprocessor conversion Caller 2 consists of two amplifiers 16 ₁ and 16 ₂ , a microprocessor 17, a set of OR elements 18, an And 21 element, an electrical signal to optical converter 19 and an optical signal to electrical converter 20, the input-output group of the microprocessor converter 2 being the input of the first amplifier 16 ₁ and the output of the second amplifier 16 ₂ , the input of which is connected to the output of the element And 21, the first input of which is connected to the third input of the set of elements OR 18 and the first output of the microprocessor 17, the input of which is connected to the output of the first of the amplifier 16 ₁ , the second output of the microprocessor 17 is connected to the first input of the set of elements OR 18, the second input of which is connected to the second input of the element And 21 and the output of the optical signal converter into electrical 20, the input of which is the input of the microprocessor converter 2, the output of which is the output a converter of electrical signals into optical 19, the input of which is connected to the output of a set of elements OR 18.

The operation of a multiprocessor system of relay protection and automation is determined by the modes:
- initialization and configuration (commissioning);
- Work.

 In the initialization mode, according to the instructions of the system administrator, the structure of the system is formed taking into account the incoming processing devices 7, the distribution according to the numbers of the distribution devices connected to the processing devices, the polling order of the processing devices is determined. At the same time, the formation and initialization of databases, including the dynamic one, which stores the parameters measured by the processing devices, as well as the values of the input and output discrete signals, takes place.

In the mode, the work is carried out:
- collection of information from processing devices in the prescribed manner, analysis of their performance;
- oscillography of electrical signals (software processing with the output of waveforms of signals to the monitor screen) both in normal mode and in emergency events;
- issuing commands to processing devices;
- filling out databases and managing them;
- Interactive interaction of the system with AWP operators;
- background self-diagnosis, during which the system (complex) performs self-monitoring of incoming components (processing devices, network components, workstations, servers) without stopping work.

 All of these operations are carried out automatically.

In the operating mode according to the operator’s commands, the switching apparatuses of the monitoring and control objects connected to the processing devices through groups of inputs and input-outputs are controlled, the complex is configured, the digital relay protection and automation system is configured and the settings are entered. The system operates as follows:
Industrial computer 1 polls the processing devices 7 according to the Master-Slave scheme. The information received from the processing devices is analyzed in the event control mode and entered into the local real-time database.

 The information collected in the database through a dedicated server 25 is provided to top-level programs, where it is visualized using the appropriate software modules on the corresponding workstation 22 of the dispatcher or engineer. Exchange between AWP is carried out via Ethernet (figure 5).

 The microprocessor converter 2 and the communication node 3 operate in the "master" or "relay" mode as follows: the processing device 7, which plays the role of a "master" in the information loop 9, provides information signals received at the input of the communication node 3, which are received through the amplifier 16 the input of the set of elements OR 18, the second input of which, at a time determined by the program, receives signals from the converter of the optical signals into electrical signals to provide relay signals. The provision of the transmit-receive or relay mode is determined by the signal level at the third input of the set of OR elements 18 and the first input of the AND element (if the level is high, then transmission and reception occurs, if it is low, then relaying - the signals pass only through the set of OR elements 18) . Next, the signals are converted into optical pulses and transmitted through the fiber optic cable to the optical input of the next communication node 3, where they are converted into electrical signals, which simultaneously enter the corresponding processing device, and are also converted into optical signals and fed to the input via the fiber-optic channel the next processing device 7. In the microprocessor converter 2, the reception, transmission and relaying of signals takes place in a similar way under the control of the microprocessor 17, respectively Wii with software.

Thus, the system has advanced functionality, as provides:
- translation of control commands from operators to high-voltage switches of inputs and connections;
- automation of the process of collecting information about the state of inputs, connections and switches of the monitoring and control facility;
- automation of the collection, analysis and storage of information about emergency processes;
- the ability to remotely configure and control the settings of microprocessor relay protection devices;
- remote collection of diagnostic information from digital relay protection and automation units.

Claims (1)

 A multiprocessor information and control system for relay protection and automation, containing N processing devices and N communication nodes, each processing device containing a processing unit and two interface nodes with a trunk, and the output of the b-th communication node (where b = 1... N- 1) connected to the input of the (b + 1) -th communication node, characterized in that a microprocessor converter is inserted into it, the information inputs and outputs of the first group of each N-th processing device connected to the information inputs and outputs of the corresponding N-th communication node , inf The rotational inputs and outputs of the second group of each Nth processing device are the first group of inputs and outputs of the system, the second group of inputs and outputs of which are the input and output groups of the Nth processing units, the first and second groups of inputs of which are a group of system inputs, output N -th communication node is connected to the input of the microprocessor converter, the output of which is connected to the input of the first communication node, the group of inputs and outputs of the microprocessor converter is the third group of inputs and outputs of the system, and the microprocessor the weedy converter consists of two amplifiers, a microprocessor, a set of OR elements, an And element, an electric to optical signal converter and an optical to electric converter, the input-output group of the microprocessor converter being the input of the first amplifier and the output of the second amplifier, the input of which is connected to the output of the element And, the first input of which is connected to the third input of the set of OR elements and to the first output of the microprocessor, the input of which is connected to the output of the first amplifier, the second output of the microprocessor is connected to the first input of the set of OR elements, the second input of which is connected to the second input of the AND element and the output of the optical signal to electrical converter, the input of which is the input of the microprocessor converter, the output of which is the output of the electrical signal to optical converter, the input of which is connected to output of a set of OR elements.

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