RU61916U1 - SIMULATOR OF A BLOCK MANAGEMENT POINT OF A FULL-SCALE SIMULATOR OF A NUCLEAR POWER INSTALLATION - Google Patents

Abstract

The inventive utility model relates to the field of energy, in particular, power simulator construction and relates to the design and operation of block control room simulators (BCPs) of full-scale simulators of power units of power plants, mainly nuclear ones, and can be used in training centers as a universal technical tool for training operators different types of nuclear power units. The task solved by this useful model is the implementation of such properties as universality, which allows simulators to train operators of several different types of power units, the control units of which have significant differences in the design of dashboards and control panels; the flexibility to easily modify the simulator of the control room when changing the means of displaying information on a real control room, as well as increasing the speed of configuring the simulator for a specific power unit is the closest analogue. The essence of the proposed technical solution consists in the fact that in the simulator of the control room block simulator of a full-scale simulator of a nuclear power plant containing a dashboard simulator, a control panel simulator with a dashboard and a computer, it is proposed that dashboards and dashboards be executed on displays, and as instrument displays panels use video cubes that provide the ability to obtain a seamless multi-screen image, and the control panel is executed in the form of modules with

unified connectors and interchangeable worktops with control panels. In addition, the computer performs control functions, and is connected to displays through a video controller and video delivery equipment. The proposed technical solutions will make it possible to create a universal simulator of a full-scale simulator simulator, increase the efficiency of simulator preparation for work, reduce costs and time required to bring a simulator of a simulator in accordance with the control unit simulators of power units - the closest analogues for their modernization.

Description

The inventive utility model relates to the field of energy, in particular, power simulator construction and relates to the design and operation of block control room simulators (BCPs) of full-scale simulators of power units of power plants, mainly nuclear ones, and can be used in training centers as a universal technical tool for training operators different types of nuclear power units.

The increasing demand for well-trained NPP operators, as well as the need to maintain the level of operator training along with the complexity of nuclear power plants in the 60s of the last century led to the creation of full-scale simulators, which are the most effective training tool in this area. A full-scale simulator of a nuclear power plant is a software and hardware modeling complex that reproduces the dynamic operating modes of nuclear power plants in real time and uses a full-scale model of a real block control point from which centralized automated control of technological processes is carried out at the nuclear power plant, implemented by operators and automation equipment. Full-scale simulators for nuclear power plants are created, as a rule, for a specific (reference) power unit and there are practically no simulators that can flexibly adapt to various types of power units and be a universal simulator. At the same time, at many operating nuclear power plants having several of the same type

power units with the same organization of centralized automated control can be different in appearance of the control unit due to the fact that work was carried out on them at different times and in different volumes to upgrade systems and equipment and extend the life of the unit. The relevance of solving the problem of "universality" and "flexibility" of full-scale simulators is enhanced by the introduction of modern display means for presenting information at BPU (projection cubes, plasma and liquid crystal panels) at existing nuclear power plants. The use of display means significantly changes the human-machine interface of the control room and with no compensating measures it is impossible to ensure the training of personnel on a full-scale simulator, the control room simulator of which was originally created on traditional means of information display. Therefore, despite the successes achieved in the global energy simulator industry, to date, the Russian and foreign developments of full-scale simulators are inherent in problematic issues consisting in the implementation of:

- a universal simulator of a BPU full-scale simulator for several different types of power units;

- mechanisms to flexibly rebuild a full-scale simulator during the modernization of NPP systems and equipment without a long stop of the simulator to upgrade and replace its technical means.

One of the analogues of the claimed utility model is a simulator of a full-scale simulator simulator described in the article: Simulator Training for Older Nuclear Power Stations - CEGB Magnox simulator / Ratclif J.A. // Proc. of the Specialists' Meeting on Training Simulators for Nuclear Power Plants, Toronto, Canada, Sept. 14-16, 1987. - IAEA, Vienna, 1987. This simulator is designed to train staff

several nuclear power plants built at different times, having different technological schemes and, accordingly, significant differences in terms of the organization of control and management at the control room. The control room simulator consists of a panel with dashboards and a control panel. To simulate the dashboards of different nuclear power plants, overhead panels are installed that are installed on the shield frame. Sets of panels are stored in the simulator room in a special rack. A transport trolley is used to move the panels. The disadvantages of the indicated simulator BPU include the complexity of the process of adjustment to a different configuration, as well as the length of production and integration with the simulator software of the simulator of new panels in case of a change in the composition / nomenclature of equipment of dashboards at power units - the closest analogues.

The closest analogue of the claimed technical solution is the simulator of the full-scale simulator control room described in the article "TSG ++: a full scope training simulator using soft panels", 2000. This control room simulator includes dashboard and control panel simulators made on displays, including using displays with touch screens, while the facades of real dashboards and control panels are reproduced using a graphical interface in the form of so-called soft panels and a computer. This solution provides the operator with the same functionality as a full-scale copy simulator. The interaction of operators with the power unit model is carried out through touch screens containing “animated” images of the controls. In order to perceive the entire graphic images of panels and eliminate the need to navigate fragments of panels, the image scale is reduced to 40-45% of the actual size.

The disadvantage of the closest analogue is that the displays used in it do not allow representing the images of the panels in full size, and touch screens do not allow the learner to manipulate the controls in a way identical to that used in real activity. It is also known that by means of computer graphics alone it is impossible to prepare an operator capable of professionally performing real tasks.

The task solved by this useful model is the implementation of such properties as universality, which allows simulators to train operators of several different types of power units, the control units of which have significant differences in the design of dashboards and control panels; the flexibility to easily modify the simulator of the control room when changing the means of displaying information on a real control room, as well as increasing the speed of configuring the simulator for a specific power unit is the closest analogue.

The essence of the proposed technical solution consists in the fact that in the simulator of the control room block simulator of a full-scale simulator of a nuclear power plant containing a dashboard simulator, a control panel simulator with a dashboard and a computer, it is proposed that dashboards and dashboards be executed on displays, and as instrument displays panels to use video cubes, providing the possibility of obtaining a seamless multi-screen image, and the control panel to execute in the form of modules with a unified E worktop assembly and removable from the control panels. In addition, the computer performs control functions, and is connected to displays through a video controller and video delivery equipment.

Despite the fact that the proposed simulator of the BPU and its closest analogue is based on the same principle - reproduction

the appearance and functions of the real control room, they differ in the way they are formed and in the means of representing the images on the displays, as well as in the design of the control panel simulators. The use of video cubes, which are large-format means of displaying information, as displays provides a seamless multi-screen image containing video images of simulated equipment in full size. The implementation of the control panel simulator in the form of a modular design with interchangeable countertops provides the ability to install sets of countertops of various configurations with full-scale copying of the controls and displays on the front side of the countertops. To ensure the connection of sets of countertops of different configurations with the input / output and power systems of the simulator, the remote control modules are equipped with connectors that are unified in design and placement. Using a video controller to distribute video signals across displays allows you to control video images regardless of their source and transmission method.

The proposed utility model is illustrated by graphic material. Figure 1 shows the layout of the simulator BPU, figure 2 shows a General view of the simulator BPU in the process of replacing the tabletops of the console, figure 3 is a structural-functional diagram of the output of video images to the displays of the simulator BPU.

The simulator of the control unit (Fig. 1) consists of a simulator of “dashboard” panels 1 assembled from video cubes, a simulator of a control panel 2 with a “dashboard” 3 assembled from flat panel monitors.

The video cubes 1 (Fig. 2) are assembled into a single seamless structure forming a video wall and mounted on a pedestal 2. The sizes of the screens of the video cubes are selected according to the dimensions of real dashboards, which allows you to visually accurately reproduce devices and tools

display information that real dashboards are equipped with. The control panel simulator consists of modules 4, designed to accommodate the console equipment (input / output system equipment, power supplies, cables, electrical fittings, etc.) and removable tabletops 5, with control and indication bodies placed on them. Module 4 consists of a supporting frame (not shown in FIG. 2) and hinged decorative and protective panels. The frame of the module is assembled from metal structures having shaped openings for connecting the modules to each other and fastening the hinged elements. Hinged elements differ in the way they are installed on the module frame. Internal hinged elements are console equipment, and all installation dimensions for their fastening are made in accordance with the standard equipment installation. External hinged elements perform a decorative and protective role. The interchangeable tabletop 5 consists of a frame (not shown in FIG. 2) and a hinged control panel 6. The frame is designed to secure the internal equipment of the tabletop 5 and control panel 6 and is a spatial frame (not shown in FIG. 2) made of shaped metal structures . The control panel 6 is used to install controls and displays similar to the equipment of a real control room. The shape and design of the countertop 5 provide the ability to install guide elements and clips for fixing it in a certain position. Guide elements with clamps are connected in a single mechanism, which has the possibility of arbitrary installation. To ensure electrical connections of removable worktops with the console equipment, the upper part of module 4 has standardized connectors 7. The contacts of connectors 7 are functionally divided into groups so that each of the groups (not shown in FIG. 2) has a strictly defined composition. Connectors 7 are located

with a certain step, which makes it possible to standardize the seats of module 4 and a removable tabletop 5. On the side of module 4 facing the operator, standard extendable shelves 8 are installed for computer keyboards. To access the console equipment, opening doors (not shown in FIG. 2) located on the rear side of the module are provided. Flat panel monitors 3 are installed along the rear upper part of the console in a continuous row, directly behind removable tabletops 5. Monitors are mounted to the remote control modules using standard brackets.

The scheme for outputting video images to displays is shown in FIG. 3. Video images generated in the simulator’s main simulator computer are transmitted to displays (video cubes and flat panel monitors) through video controller 1. Simulated images can be randomly mixed with images received in the form of video signals from other systems integrated into the computer complex of a full-scale simulator, including television sources analog signals. Remote control, mixing, scaling and location on the video displays is carried out using the control computer 2, on which software is installed that allows you to control the video controller. Video signals are transmitted by means of video signal delivery equipment including DVI-I video extenders, consisting of transmitting 3 and receiving 4 modules connected by a standard cable based on twisted pair cable. The transmitters 3 are installed in the immediate vicinity of the video controller 1, the receivers 4 are mounted inside the console.

The work on bringing the configuration of the BPU simulator in accordance with a specific power unit includes two stages: setting up the control panel simulator and loading the prototype power unit model and video images on the main modeling computer. In the process of setting up the control panel simulator, the following actions are performed (see figure 2):

- transportation of a set of interchangeable worktops 5 with the help of a trolley having guides and latches designed for docking with the guides of the modules 4;

- installation of interchangeable countertops 5 on the console, consisting in docking and fixing the trolley, moving the countertops 5 along the guides from the trolley to the console, docking with standardized connectors 7, securing with lock latches and undocking the trolley;

- turning on the power of the console simulator;

- testing the input / output system.

The advantage of this BPU simulator is that with its implementation there is no need to build several full-scale simulators for different power units (the costs of creating a full-scale simulator for a nuclear power unit with an electric power of 1000 MW are currently estimated at 200 million rubles). An additional advantage is the reduction to a minimum of costs for bringing the simulator of the control unit in accordance with the control unit of the power units - the closest analogues during their modernization, as well as the absence of expenses for maintenance and repair of the numerous equipment of the control unit dashboards.

Claims (2)

1. A simulator of a control room block of a full-scale simulator of a nuclear power plant, comprising a dashboard simulator, a control panel simulator with a dashboard and a computer, characterized in that the dashboards and dashboards are made on displays, and videocubes are used as dashboard displays to enable obtaining a seamless multi-screen image, and the control panel is made in the form of modules with standardized connectors and removable worktops with control panels. 2. The simulator of the block control point according to claim 1, characterized in that the computer performs control functions and is connected to displays through a video controller and video signal delivery equipment.