RU147249U1 - MEASURING TERMINAL FOR ELECTRICAL PARAMETERS MEASUREMENT SYSTEMS WITH FLEXIBLE DYNAMIC REDISTRIBUTION OF FUNCTIONS BETWEEN TERMINALS - Google Patents

Abstract

1. The measuring terminal for electrical parameter measurement systems with flexible dynamic redistribution of functions between the terminals, including a unit for performing measurement functions, characterized in that it further includes a module for dynamic distribution of functions associated with the unit for performing measurement functions, where the module for dynamic distribution of functions made with the possibility of receiving and storing individual measurement functions received by this terminal from external devices via communication channels, including t of other similar terminals in the measurement system, with the possibility of performing redistribution of functions, including the transfer of individual functions stored in the module to another similar terminal in the measurement system via a communication channel with the subsequent removal or without removal of transferred functions from the module, loading of individual stored in the module functions to the unit for performing measurement functions of a given terminal and the removal of individual functions from the composition of the unit for performing measurement functions of this terminal with ensuring you completing the above operations of loading and deleting without affecting the operation of other measurement functions as part of the unit for performing the measurement functions of this terminal, as well as with the possibility of identifying critical states of the distribution of functions between the measuring terminals in the measurement system based on the results, including those carried out by this module of information interaction communication channels with other measuring terminals in the measurement system and / or with modules for dynamic distribution of functions as part of the indicated terms

Description

FIELD OF TECHNOLOGY

The utility model under consideration relates to secondary measuring instruments intended for use as part of automated measuring systems, which include a combination of the above instruments and allowing the implementation of flexible dynamic redistribution of measuring functions between individual instruments with the goal, in particular, of increasing the fault tolerance of individual system functions.

BACKGROUND

There are well-known programmable controllers SIMATIC S7-400H on the market from the manufacturer Siemens (Germany) [1], which provide building on their basis of automated systems with redundancy (including measurement systems), where each of the above systems with redundancy is built on the basis of a pair of specified controllers with their full duplication. The disadvantage of the above controllers when building redundant automation systems on their basis is the excessively high redundancy of hardware in redundant systems (characterized by complete duplication of the system hardware components), which is not always optimal and may, in particular, cause unreasonably high cost of a redundant automation system .

Also known are the TREI-5B-02 software control devices (controllers) offered on the market and selected as a prototype (manufacturer - TREI Gmbh, Germany) [2], intended for use, including as part of software and hardware systems (PTC) KRUG-2000 series (manufacturer of complexes - NPF KRUG, Russia) [3] as secondary measuring instruments. When operating the TREI-5B-02 controllers as part of the KRUG-2000 PTK, it is possible to provide 100% hot backup of these controllers. At the same time, the controllers themselves include a self-diagnosis function with the ability to automatically issue a signal to an external device, for example, another similar controller, which in this case takes on the task of performing the measurement functions of the failed controller. The disadvantage of the prototype is the lack of the ability to reserve individual measurement functions in the controller, in particular, only critical measurement functions (for example, electricity metering functions), and not the entire controller (including, possibly, less important measurement functions present in the controller, for example , functions of current measurements of electrical parameters performed for the purpose of visualization and control of the current electro-energy mode by the personnel of the power facility), h This excludes the possibility of using redundancy solutions as part of the measurement systems that are sufficiently optimal in terms of the number of devices and, therefore, in terms of the cost of redundancy schemes, and this, in turn, leads to an increased cost of redundant measurement systems.

DISCLOSURE OF A USEFUL MODEL

The technical result of the utility model under consideration is to ensure a more optimal use of the hardware of the systems for measuring electrical parameters with redundancy, which results in a decrease in the amount of the reserve of hardware components required in the measurement system.

The above technical result is achieved due to the fact that the proposed measuring terminal, when used as part of electrical parameter measurement systems, allows flexible and efficient redistribution of measurement functions between this measuring terminal and other similar terminals in the measurement system, where the above redistribution is carried out automatically during normal operation measurement systems and includes the possibility of redistributing complete sets of measuring functions of individual terminals, but also individual functions from the composition of the above sets, which allows, in particular, to provide the possibility of backing up only part of the functions from the composition of measuring terminals, for example, only critical measurement functions (functions of accounting for the amount of electricity, etc. .). Due to the possibility of backing up only part of the functions of the measuring terminals (in particular, only critical functions), and not the complete sets of measuring functions of individual terminals, the hardware resources of the above terminals are released, due to which it is possible to reduce the number of reserve hardware components in the measurement system (measuring terminals), which ensures the achievement of the claimed technical result, or the indicated released hardware resources m Gut be deployed for additional reserve function measurement system, which contributes to further increase the reliability of the measurement system of its functions.

The claimed measuring terminal is characterized in that it includes a unit for performing measurement functions and, unlike the prototype, further includes a module for dynamic distribution of functions, which is associated with a unit for performing measurement functions of this terminal. The above module provides reception and storage of measurement functions received from devices external to a given terminal via communication channels, including other similar terminals in the measurement system, and also provides redistribution of functions, where redistribution of functions includes transmission individual functions stored in the module to another similar terminal in the measurement system via the communication channel with subsequent removal or without removal of the transferred functions from the module, for loading of individual functions stored in the module into the unit for performing measurement functions of a given terminal and removal of individual functions from the composition of the above block, ensuring the above-mentioned loading and deleting operations without affecting the operation of other measurement functions in the unit for performing measurement functions of this terminal. In addition, the module of the dynamic distribution of functions of the terminal identifies critical states of the distribution of functions between the measuring terminals in the measurement system according to the results, including that carried out by this module of information interaction through communication channels with other measuring terminals and / or with modules of dynamic distribution of functions as part of other similar terminals in the measurement system, and also carries out information interaction with dynamic distribution modules Nia functions of other terminals in the measurement system to determine whether to perform the data module based on the functions of redistribution operations identified critical functions in a system with distribution of states performing the respective functions of redistribution operations in case of the above need. Moreover, the above critical states of the distribution of functions between the measuring terminals in the measurement system may include, for example:

- failure of at least one of the measurement terminals of the measurement system;

- failure of at least one of the measurement functions in the unit for performing the measurement functions of one of the measuring terminals of the system;

- an increase in the estimated probability of failure of at least one of the measuring terminals of the measurement system, due, for example, to an increase in the computing and communication load on the above terminal or to a decrease in the residual life of the above terminal, determined from the internal self-diagnosis of the current state of the terminal;

- the occurrence of non-optimality in the distribution of functions between individual measuring terminals in the measurement system, where the above non-optimality is manifested, for example, in the uneven distribution of the computing and communication load between the terminals or, for example, in the incompleteness of the computing and communication load in some of the measuring terminals in the system;

- disconnection from the measurement system of at least one of the measurement terminals;

- connection to the measurement system of at least one new measuring terminal.

At the same time, the redistribution of functions provided by the claimed measuring terminal, in particular, the identification by the module of the dynamic distribution of terminal functions of the need to perform redistribution of functions with the corresponding redistribution of functions, if necessary, can be carried out on the basis of, in particular, balancing the reliability of the function in the measurement optimal (with the minimum necessary level of redundancy) use of hardware res courses of the measurement system (in particular, measuring terminals).

In the particular case of the implementation of the utility model, when the module of the dynamic distribution of functions of the terminal provides the identification of critical states of the distribution of functions in the measurement system in the form of events when the measuring terminals are disconnected from the system and / or in the form of events when new measurement terminals are connected to the measurement system with the corresponding redistribution of functions, ensures the achievement of an additional technical result, which consists in reducing the complexity of the implementation I reconfiguration of the measurement system in cases, respectively, when new measurement terminals are connected or added to the system and / or when separate measurement terminals are disconnected from the system, for example, in order to decommission them.

BRIEF DESCRIPTION OF THE DRAWINGS

Figure 1 shows a diagram describing the composition of the main blocks of the claimed measuring terminal, the structure of the informational relationships of the main blocks of the terminal, as well as the main mechanisms of informational interaction of the measuring terminal with other similar terminals in the electrical parameters measurement system with flexible dynamic redistribution of functions between the terminals.

IMPLEMENTATION OF A USEFUL MODEL

The claimed measuring terminal 1 (see Fig. 1) includes a unit 2 for performing measurement functions and a module 3 for dynamic distribution of functions. Module 3 as part of measuring terminal 1 provides reception 4 and storage of functions 5 received from external devices via communication channels 6. In addition, module 3 as part of terminal 1 provides redistribution of functions, including the transfer of 8 separate functions stored in module 3 5 to another measuring terminal 7 with the subsequent removal of 9 or without deleting the transferred functions from the module 3, loading 10 functions into the block 2 of the measurement functions of terminal 1, removing 11 functions from the block 2 s is provided we perform operations 10 and 11 without affecting the operation of the measurement functions 12 already existing in block 2. Also, module 3 of terminal 1 detects critical states of the distribution of functions in the measurement system based on the results, including that carried out by this module of information interaction with other measuring terminals 7 via communication channels 6, and also, possibly, according to the results of internal self-diagnosis of the current state of terminal 1. In addition, module 3 of terminal 1 carries out information interaction 13 with the mode lyami 3 7 other terminals in the system measurements to determine whether to perform data operations redistribution module 3 functions on the basis of the identified critical functions in the system of distribution of states with the performance of the corresponding functions of redistribution operations in case of necessity.

The claimed terminal 1 can be implemented as a microprocessor electronic device. Unit 2 for performing measurement functions as part of the terminal can be implemented as a set of connected electronic components, including a microprocessor, memory modules (operational and / or non-volatile), etc. In order to minimize the impact of the operations of redistributing functions (in particular, the operations of loading functions into block 2 from module 3, or deleting functions from terminal block 2) on the operation of measuring functions as part of terminal block 2, terminal module 3 is implemented as a separate computing module (board), which contains, in particular, a microprocessor and memory, and is connected to the unit 2 via the internal data bus of the measuring terminal. Moreover, in order to unify the measurement terminals intended for use as part of electrical parameter measurement systems with flexible dynamic redistribution of functions between the measurement terminals, module 3 of the claimed measurement terminal can be configured to store measurement functions 5 and transfer 8 of these functions to other terminals 7 in the form sets of function blocks made according to a single standard, for example, in accordance with the specification IEC 61499 [4].

In the particular case, the measuring terminal can be implemented with a module for dynamic distribution of functions, which initially already contains a complete set of measuring functions used within the framework of an automated measurement system. Or the terminal can be configured before being used as part of an automated measurement system in such a way that the dynamic distribution module of the terminal functions contains a full set of measurement functions used within the system. At the same time, the information exchange between this terminal and other similar terminals in the measurement system related to the dynamic redistribution of functions consists only in activating one or another set of functions already loaded into the terminals, without requiring transfer between the terminals and loading of the functions themselves into the terminals the process of regular functioning of the measurement system. In this case, the communication load on the communication channels between the terminals is reduced, and it is also possible to increase the speed of performing redistribution of functions in the measurement system, which, in turn, helps reduce the time of possible inoperability of individual functions in the measurement system in the case of, for example, individual measurement failures terminals, and, therefore, provides an increase in the availability factor of the above measurement functions in the system.

INFORMATION SOURCES

1. “SIMATIC Automation System S7-400H Fault-tolerant Systems. Manual »/ A5E00068197-07, 07/2006 (Order number: 6ES7988-8HA11-8BA0) (SIMATIC S7-400H Automation System Guide: Edition 07/2006, manufacturer's order number: 6ES7988-8HA10-8BA0).

2 TREI1.421457.101-00.РЭ “Device for program control TREI-5B-02. Operation manual ”(electronic version of the manual is on the website of the Russian representative office of the manufacturer: http://trei-gmbh.ru).

3 I.A. Elizarov, Yu.F. Martemyanov, A.G. Skhirtladze, S.V. Frolov “Technical means of automation. Software and hardware complexes and controllers: Textbook "/ M.:" Publishing House Engineering-1 ", 2004.

4. IEC 61499-1 Ed. 1.0 (2005-01-24) “Function Blocks - Part 1: Architecture”.

Claims (2)

1. The measuring terminal for electrical parameter measurement systems with flexible dynamic redistribution of functions between the terminals, including a unit for performing measurement functions, characterized in that it further includes a module for dynamic distribution of functions associated with the unit for performing measurement functions, where the module for dynamic distribution of functions made with the possibility of receiving and storing individual measurement functions received by this terminal from external devices via communication channels, including t of other similar terminals in the measurement system, with the possibility of performing redistribution of functions, including the transfer of individual functions stored in the module to another similar terminal in the measurement system via a communication channel with the subsequent removal or without removal of transferred functions from the module, loading of individual stored in the module functions to the unit for performing measurement functions of a given terminal and the removal of individual functions from the composition of the unit for performing measurement functions of this terminal with ensuring you completing the above operations of loading and deleting without affecting the operation of other measurement functions as part of the unit for performing the measurement functions of this terminal, as well as with the possibility of identifying critical states of the distribution of functions between the measuring terminals in the measurement system based on the results, including those carried out by this module of information interaction communication channels with other measuring terminals in the measurement system and / or with modules for dynamic distribution of functions as part of the indicated terms of inals, as well as, possibly, based on the results of internal self-diagnosis of the current state of this terminal, and the possibility of information interaction via communication channels with modules for dynamic distribution of functions of other similar terminals in the measurement system in order to identify the need for this module to perform redistribution of functions based on the critical states of the distribution of functions with the implementation of the corresponding operations of the redistribution of functions in case of identification awns. 2. The terminal according to claim 1, characterized in that the critical states of the distribution of functions in the measurement system detected by the dynamic distribution module of the functions of the terminal include a failure of at least one of the measurement terminals of the measurement system and / or a failure of at least at least one of the measurement functions as part of the unit for performing the measurement functions of one of the measuring terminals of the system and / or increasing the estimated probability of failure of at least one of the measuring terminals of the measurement system, caused, for example, by an increase in the computational and communication load on the aforementioned terminal or a decrease in the residual life of the aforementioned terminal, determined by the internal self-diagnosis of the current state of the terminal, and / or the emergence of non-optimality in the distribution of functions between individual measuring terminals in a system where the above non-optimality is manifested, for example, in the uneven distribution of the computing and communication load between the terminals or, for example, in the incomplete numerals and communication load at a part of the measuring terminals in the system, and / or disconnected from the measurement system, at least one of the measuring terminals and / or connecting to the measuring system, at least one new measurement terminal.

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