RU82048U1 - STRUCTURED MONITORING AND MANAGEMENT SYSTEM FOR BUILDING AND STRUCTURE ENGINEERING SYSTEMS - SMIS - Google Patents

Abstract

1. A structured monitoring and control system for engineering systems of buildings and structures, comprising a central computing module with at least one computer server station, which is connected to at least one block of engineering systems and configured to collect operation parameters of engineering systems, creating a database of current parameters of engineering systems, determining trends in the parameters of engineering systems and creating a database of trending parameters, extrapolating trend values measuring the parameters of the engineering systems for a constant time interval, modeling the operation of engineering systems and determining the calculated values of the parameters and their maximum permissible values, forming a database of the calculated parameters and their maximum permissible values, comparing the current parameters of the system with the calculated parameters and their maximum permissible values, comparing extrapolated values and values of current operating parameters with calculated parameters and their maximum permissible values, determining possible consequences, damage assessment and recommendations for responding to the results of computer modeling in case of exceeding the absolute values of the current parameters and / or extrapolated to a constant time interval values of the current parameters of the engineering systems, the corresponding values of the calculated parameters of the engineering systems by values exceeding the threshold values, fixing the state the operation of engineering systems and / or the predicted state of operation of engineering systems and an assessment of the possible consequences, you

Description

The utility model relates to the field of automated control systems, and specifically to a structured monitoring and control system for engineering systems of buildings and structures - SMIS. The utility model can be used in the design and construction of high-rise and unique buildings, buildings and structures for special purposes, including office buildings, sports facilities, museum and exhibition complexes, industrial enterprises, as well as in the reconstruction and restoration of buildings and structures related to cultural heritage, the safety of which requires special attention.

A well-known structured monitoring and control system for the engineering equipment of the facility (RU No. 2133490 C1, IPC 6 G05B 15/00, 1999) is used to ensure complete monitoring and centralized management of the building's life support engineering systems.

The system comprises a central computing module with an input / output device connected via communication nodes to a centralized power system and units for autonomous control of equipment of an object.

The central computing module is a programmable computer server station with functions in accordance with the software for centrally receiving monitoring data via information channels within the framework of a unified network protocol, processing these data and issuing control signals to control units and units of the engineering equipment of the facility.

The system includes controllers located in the locations of communication nodes connected to the central cross of the centralized power system and autonomous control units for engineering equipment according to a hierarchical star scheme or bus scheme. The controllers are connected according to the hierarchical star scheme or according to the bus scheme to the input-output device of the central computing module. To each controller in series or according to the scheme of the indicated star, remote input-output modules are connected, each of which is connected to an appropriate sensor for monitoring, measurement, control, control devices for specific units or units of the engineering equipment of the object.

The system includes one or more additional computer stations. An additional computer station with its I / O module is connected via a local computer network to a central computing module and a dedicated channel with an appropriate controller to provide, in accordance with the software for local monitoring and control of nodes and assemblies, at least one functionally independent part of the building’s engineering equipment, and additional computer stations are interconnected via an information channel according to a hierarchical star scheme through concentrators -local computer networks, located in dedicated channels.

The well-known structured monitoring and control system for the engineering equipment of an object carries out only operational monitoring of the current parameters of the engineering support and, accordingly, the operational management of engineering equipment without forecasting the parameters of the engineering systems and the occurrence of emergency situations. For these reasons, the known system does not exclude the possibility of emergency situations.

The technical result, which provides a real utility model, is to develop a structured monitoring and control system for engineering systems of buildings and structures, which will predict the occurrence of emergency situations, which will ensure high reliability of functioning of both engineering systems of buildings and structures, and their service systems aimed to solve problems of a particular building or structure for a specific purpose.

Achieving this result is ensured by a structured monitoring and control system for engineering systems of buildings and structures, which contains a central computing module with at least one computer server station.

The central computing module is connected to at least one block of engineering systems and is configured to collect operating parameters of engineering systems, form a database of current parameters of engineering systems, determine trends in operating parameters of engineering systems and generate a database of trend trends, extrapolate the trend values of work parameters engineering systems for a constant time interval, modeling the operation of engineering systems and determining the calculated values of the parameters and their maximum permissible values, the formation of a database of calculated parameters and their maximum permissible values, comparing the current parameters of the system with the calculated

parameters and their maximum permissible values, comparing extrapolated values and values of current operating parameters with calculated parameters and their maximum permissible values, determining possible consequences, assessing damage and responding recommendations based on computer simulation if the absolute values of the current parameters and / or extrapolated to constant time interval of the values of the current operating parameters of engineering systems of the corresponding values of the calculated parameters of bots of engineering systems by values that exceed thresholds, fixing the state of operation of engineering systems and / or the predicted state of operation of engineering systems and assessing the possible consequences caused by an emergency, and recommendations for responding to emergency situations, as well as the formation of management teams of the engineering system in automatic and / or semi-automatic mode with the participation of the operator.

The central computing module may be associated with at least a portion of the engineering systems selected from the group including:

- a monitoring, control and dispatching system that provides a set of maintenance tools for automatic control, monitoring and optimization of human intervention and administration in order to ensure energy-efficient, economical and safe operations for maintenance of building equipment (Industry Standard NP ABOK, Automation Systems and building management, ABOK STANDARD-5-2004, Part 2. General provisions. Hardware.),

- a communication system that provides a set of technical means, providing information exchange between the automated workers of maintenance personnel and automatic systems and made in the form of a telecommunication network based on wired and / or wireless means of communication,

- fire alarm system, providing a set of technical means designed to detect fires,

- fire extinguishing system, providing a set of technical means designed to extinguish a fire,

- smoke removal system, providing a set of technical means designed to remove smoke,

- a warning system that provides a set of technical tools designed for information alerts people,

- a system of passenger-and-freight elevators, providing for a complex of technical means designed for lifting and lowering people and goods,

- a system of fire lifts and elevators, providing a set of technical equipment designed for emergency emergency ascent and descent of people,

- access control and management system that provides a set of technical means designed to control and provide authorized access to or from a room, building, structure, zone and territory (Requirements for technical means and systems for comprehensive security, automation and communication of multi-functional high-rise buildings and complexes . M.: VAN KB, 2005, p. 20.),

- a security-alarm-ringing system, which provides a set of technical means for detecting unauthorized actions, informing personnel, automatically submitting control commands to executive devices (Requirements for technical means and systems for comprehensive security, automation and communication of multi-purpose high-rise buildings and complexes. M .: VAN KB, 2005, p. 19.),

- the perimeter security system, which provides a set of technical means designed to detect unauthorized actions to penetrate the protected area, inform staff and to automatically send control commands to executive devices,

- a television surveillance system that provides a set of technical means for remote monitoring (Requirements for technical means and systems for the integrated security, automation and communication of multi-functional high-rise buildings and complexes. M .: VAN KB, 2005, p.22; a television monitoring system is being created , as a rule, in accordance with GOST R51558),

- a security lighting system that provides a set of technical means designed for the operation of technical equipment and object security in the dark (Requirements for technical means and systems for the integrated safety, automation and communication of multi-purpose high-rise buildings and complexes. M .: VAN KB, 2005, p. 28; the security lighting system, as a rule, is created in accordance with SNiP 23.05-95),

- emergency lighting system, providing a set of technical means designed to control emergency lighting (Requirements for

technical means and systems for comprehensive security, automation and communication of multifunctional high-rise buildings and complexes. M .: VAN KB, 2005, p. 33; The emergency lighting system, as a rule, is created in accordance with SP 31-110-2003),

- a management system for the evacuation of people, providing a set of technical tools designed to alert people and manage life support systems (Requirements for technical means and systems for the integrated security, automation and communication of multifunctional high-rise buildings and complexes. M .: VAN KB, 2005, p. 33 .)

- a physical protection system that provides a set of technical means designed to prevent unauthorized actions,

- emergency communication system, which provides a set of technical means for exchanging voice information (Requirements for technical means and systems for the integrated security, automation and communication of multifunctional high-rise buildings and complexes. M: VAN KB, 2005, p. 33.),

- a system for monitoring the technical condition of building structures, providing a set of technical means designed to detect places of damage and destruction,

- a system for monitoring and detecting chemical, radiation, explosive and biohazardous substances, which provides a set of technical tools designed to detect leaks of radioactive and chemical substances, as well as the presence of explosive and biohazardous substances.

- an information security system that provides a set of technical means designed to determine the modes of operation of objects (Requirements for technical means and systems for the integrated security, automation and communication of multi-functional high-rise buildings and complexes. M: VAN KB, 2005, p. 27.),

- a system of external monitoring and warning of emergency situations, which provides for a set of technical tools designed to detect and alert about the threat of an emergency.

The central computing module in the best embodiment includes a database of current operating parameters, a database of trends in operating parameters, a block for extrapolating trends, a block for modeling and determining calculated values of operating parameters, a database for calculated parameters, a comparison unit, a threshold device, a block for modeling and determining the consequences of freelance

situations and recommendations for response, a unit for generating and transmitting messages and control commands, a control unit, while the first output of the engineering systems unit is connected to the input of the unit for collecting and processing work parameters, the second output of the engineering systems unit is connected to the input of the unit for modeling work and determining calculated values parameters, the first output of the unit for collecting and processing operation parameters is connected to the database of trending parameters, the second output of the unit for collecting and processing operation parameters is connected to the database of current pa parameters, the output of the block for modeling work and determining the calculated parameters is connected to the database of calculated parameters, the output of the database of trending parameters is connected to the block of extrapolation of trends, the outputs of the block of extrapolation of trends, the database of current parameters, the database of calculated parameters are connected to the inputs of the comparison block, the output of which connected to the input of the modeling unit and determining the consequences and recommendations for response, the output of which is connected to the input of the unit for generating and transmitting messages and control commands Lenia, whose output is connected to an input of an engineering system control unit.

The unit for generating and transmitting messages and control commands, and / or the unit for modeling and determining the consequences and recommendations for the response, and / or the unit for modeling the operation of engineering systems and determining the calculated values of the parameters in the preferred embodiment of the utility model includes a geographic information system.

Communication lines of functional blocks, as a rule, are either wired communication lines, or wireless communication lines, or combinations of wired and wireless communication lines (LAN, INTERNET, SMS, WiFi, etc.).

Figure 1 shows a block diagram of a structured monitoring and control system for engineering systems of buildings and structures, which includes a block of engineering systems 1, a block for collecting work parameters 2, a database of trend parameters 3, an extrapolation block for trends 4, a database of current parameters 5, block modeling of work and determining the calculated values of parameters 6, the database of calculated parameters 7, a comparison unit 8, a threshold device 9, a block for modeling and determining the consequences and recommendations for response 10, a formation unit and soap has messages and control commands 11, an engineering system 12 control unit.

A structured monitoring and control system for engineering systems of buildings and structures provides for the automatic execution of operations with engineering systems of buildings and structures, which include:

- collection of operation parameters of engineering systems of buildings and structures, which are understood as operational parameters characterizing the operation of the engineering system itself (for example, the operating time of the circulation pump) or technical parameters characterizing the result of the engineering system (for example, pressure in the water supply system);

- formation of a database of current parameters of engineering systems;

- definition of trends in the parameters of engineering systems and the formation of a database of trending parameters;

- extrapolation of trend values of the parameters of the engineering systems for a constant time interval;

- modeling of engineering systems and determining the calculated values of the parameters and their maximum permissible values;

- the formation of a database of design parameters and their maximum permissible values;

- Comparison of the current operating parameters of engineering systems with the calculated parameters and their maximum permissible values;

- comparison of extrapolated values and values of current operating parameters with the calculated parameters and their maximum permissible values;

- determination of possible consequences, damage assessment and recommendations on the response based on the results of computer modeling in case of exceeding the absolute values of the current parameters and / or extrapolated to a constant time interval values of the current parameters of the engineering systems, the corresponding values of the calculated parameters of the engineering systems by values that exceed the threshold values;

- fixing by transmitting over the telecommunication networks the current state of operation of engineering systems and / or the predicted state of operation of engineering systems and assessing the possible consequences caused by the occurrence of an emergency situation, and recommendations for responding to emergency situations,

- the formation of management teams for engineering systems in automatic and / or semi-automatic mode with the participation of the operator.

The value of the time interval over which the trend values of the engineering system operation parameters are extrapolated can be chosen equal to an hour, a day, a week, a month, one or several years. Modeling can be carried out using software packages of finite element analysis, as well as using a geographic information system.

Performing operations in an automatic mode is carried out with a group of engineering systems mounted in a building or structure or with all systems listed in the above list of engineering systems of a building or structure.

For each engineering system, the controlled parameters of the engineering system are determined, which are received and processed in the unit for collecting and processing the parameters of the engineering system 2.

For example, for an engineering monitoring, control and dispatch system, the following parameters can be defined:

- system status (on / off);

- serviceability of the system (serviceable / accident);

- operating mode (manual / automatic);

- device malfunction: type, status, location (example: lack of voltage at the input of control cabinets; violation of the integrity of the system communication lines, signal hardware failure; software failure);

- device operation parameters (operation parameters of ventilation and air heating devices; operation parameters of heating devices, a heating unit, roof and drain heating; operation parameters of smoke ventilation devices; operation parameters of sewage, drainage and drainage water supply devices; operation parameters of cooling devices; operation parameters of devices power supply and lighting (high-voltage devices and relay devices, diesel generator sets, transformer substations, main distribution flax boards and uninterruptible power supplies, interior lighting, exterior lighting and advertising lighting area), parameters of the passenger and elevator systems.

The following parameters can be defined for a fire extinguishing system:

- system status (on / off);

- serviceability of the system (serviceable / accident);

- operating mode (manual / automatic);

- device malfunction: type, status, location (example: lack of power in the control circuits of pumps (workers, standby, jockeys), malfunction of valves and valves, leakage signal from the system);

- parameters of the operation of the devices: the current value of the water pressure, the status of the valves and valves of the system, the operation of the flow switch.

The following parameters can be defined for a fire alarm system:

- system status (on / off);

- serviceability of the system (serviceable / accident);

- signal the occurrence of a fire (indicating the location);

- state of the Fire alarm buttons (pressed / depressed);

- device malfunction: type, status, location (example: lack of power to cabinets, control panels, panels and elements of the fire alarm system).

The following parameters can be defined for the evacuation management system:

- system status (on / off);

- serviceability of the system (serviceable / accident);

- device malfunction: type, status, location (example: lack of power to cabinets, control panels, panels and elements, open communication lines).

The following parameters can be defined for a burglar alarm system:

- system status (on / off);

- serviceability of the system (serviceable / accident);

- malfunction of devices: type, status, location (example: lack of power to cabinets, control panels, remote controls and elements, open communication lines);

- signal “unauthorized entry”.

For a television surveillance system, the following parameters can be defined:

- system status (on / off);

- serviceability of the system (serviceable / accident);

- malfunction of devices: type, status, location (example: lack of power to cabinets, control panels, remote controls and elements, open communication lines);

- signal “Attention” (detection of an emergency).

The following parameters can be defined for the access control system:

- system status (on / off);

- serviceability of the system (serviceable / accident);

- device malfunction: type, status, location (example: lack of power to cabinets, control panels, panels and elements, open communication lines).

The following parameters can be determined for a system for monitoring the technical condition of building structures:

- system status (on / off);

- serviceability of the system (serviceable / accident);

- malfunction of devices: type, status, location (example: lack of power to cabinets, control panels, remote controls and elements, open communication lines);

- a signal about the stress-strain state of structures (Possible values: “Normal”, “Increased attention”, “Danger”),

For a telecommunication system, the following parameters can be defined:

- system status (on / off);

- serviceability of the system (serviceable / accident);

- device malfunction: type, status, location (example: lack of power to cabinets, control panels, panels and elements, open communication lines).

In the unit for modeling work and determining the calculated values of parameters 6 for each engineering system, the calculated values of the working parameters of engineering systems are fixed based on existing standards (MGSN 4.19-05 and others) and / or computer modeling, determining the working parameters (pressure, stress-strain condition, temperature, time of fire extinguishing, time of evacuation, etc.). These results are recorded in the database of calculated parameters 7.

For example, the following parameters can be defined:

- pressure in the heat supply system at various temperature conditions;

- pressure in the water supply system at different times of the day;

- average daily electricity consumption, maximum peak load per day;

- standard parameters of engineering systems and the facility (threshold values for the operation of smoke sensors, temperature and humidity conditions of rooms, etc.).

Based on the results of processing the operating parameters of engineering systems, in the unit for collecting and processing the operating parameters of engineering systems 2, a database of trends of parameters 3 and a database of current parameters are formed 5. At the same time, the database of current parameters 5 contains values of current parameters, and the database of trends of parameters 3 contains information about changing parameters calculated on the basis of current and previous parameter values.

For example, in the above example, the trend database of parameters 3 may contain the following parameters:

- pressure change in the heat supply system (for example, in the form of the dependence of the daily average pressure in the system on time);

- change in pressure in the water supply system (for example, in the form of the dependence of the average daily pressure in the system on time);

- change in the operating time of the charge pump in the form of the dependence of the daily (weekly, monthly, etc.) running time of the charge pump on time;

- change in the frequency of turning on the charge pump in the form of the dependence of the number of starts of the charge pump per day (week, month, etc.) on time;

- change in power consumption (for example, in the form of a daily average power consumption versus time or maximum peak load during a day versus time);

The trend database of parameters 3 may also contain other time-varying parameters of the operation of engineering systems.

Then the parameters are extrapolated in the extrapolation unit of trends 4 for a given time interval, thus determining the forecast (future) values of the parameters. The extrapolation of parameters can be carried out on the basis of the patterns identified in the modeling of the operation of engineering systems in the unit for collecting and processing parameters of the engineering systems 2.

For example, if there is a gradual leak in the fire extinguishing system, heat supply system, water supply system or if there is a gradual increase in electricity consumption, in the extrapolation unit of trends 4, the forecast (future) values of these parameters after a specified period of time (day, month, quarter, year, etc. depending on the rate of change of parameters).

Predicted values can also be calculated on the basis of operational characteristics, for example, pump running hours. In this case, the system, based on the operating modes of the pump and the frequency of its operation, predicts a parameter - the running time of the pump for a given time interval, which is then compared with the maximum permissible value of this parameter.

In the comparison unit 8, the current parameters are compared from the database of current parameters 5 and their corresponding calculated parameters stored in the database of calculated parameters and maximum permissible values 7.

Upon receipt of predictive information from the extrapolation unit of trends 4, they compare future (predicted) parameter values and

the corresponding design parameters stored in the database of design parameters and maximum permissible values 7.

The results of comparing the current parameters with the calculated parameters, and / or the predicted parameters with the calculated parameters, are input to the threshold device 9. If the threshold specified in the threshold device 9 is exceeded, the information is sent to the modeling and determination of consequences and recommendations for response 10.

In the block for modeling and determining the consequences and recommendations for response 10, the modeling of consequences is carried out for given current and / or forecast parameters, among which one or more parameters have exceeded the threshold specified in the threshold device 9.

For example: the predicted value of the parameter "running hours of the pump" after 1 year exceeds the maximum allowable number of hours worked for this type of pump.

Based on the results of determining the consequences, recommendations for response are formed. For example, when the circulating pump of the heating system is turned off, the pressure in the heating system will drop below the permissible value and part of the building will not be heated. Possible damage may amount to 100,000 rubles. per day (calculated based on the cost of additional electricity for heating and obligations under lease agreements).

An example of calculating the pressure drop in the heating system is illustrated in the screenshots presented in figure 2 (pressure in the heating system in normal mode) and figure 3 (pressure in the heating system in case of failure of the circulation pump). This example shows the possibility of using geographic information systems for modeling the consequences of the forecast (occurrence) of emergency situations.

To obtain operational information from engineering systems in the event of an emergency (triggering of threshold device 9), possible consequences can also be determined.

For example, an engineering system for television surveillance discovered an unfamiliar object (a package, an unidentified car, etc.). The signal is transmitted and processed by the modeling and determination unit of consequences and recommendations for response 10, possible scenarios of the development of events are determined - the volume of an unidentified object and the possible equivalent of explosive power are estimated. If this situation was not pre-modeled in the modeling block

and determining the consequences and recommendations for response 10, modeling of the development of the scenario when the explosive device is triggered is carried out. Possible damage is assessed and recommendations for response are determined, including evacuation of people.

Information on the consequences and recommendations on the response is received at the input of the unit for generating and transmitting messages and control commands 11, in which messages of a given format are generated for transmission to the operator (owner, tenant, operational service, city dispatch services. If necessary, determined by the user of the system, the transfer of control commands to the control unit of engineering systems 12 in accordance with the recommendations on the response (for example, unlock e escape routes in case of fire).

Claims (5)

1. A structured monitoring and control system for engineering systems of buildings and structures, comprising a central computing module with at least one computer server station, which is connected to at least one block of engineering systems and configured to collect operation parameters of engineering systems, creating a database of current parameters of engineering systems, determining trends in the parameters of engineering systems and creating a database of trending parameters, extrapolating trend values measuring the parameters of the engineering systems for a constant time interval, modeling the operation of engineering systems and determining the calculated values of the parameters and their maximum permissible values, forming a database of the calculated parameters and their maximum permissible values, comparing the current parameters of the system with the calculated parameters and their maximum permissible values, comparing extrapolated values and values of current operating parameters with calculated parameters and their maximum permissible values, determining possible consequences, damage assessment and recommendations for responding to the results of computer modeling in case of exceeding the absolute values of the current parameters and / or extrapolated to a constant time interval values of the current parameters of the engineering systems, the corresponding values of the calculated parameters of the engineering systems by values exceeding the threshold values, fixing the state the operation of engineering systems and / or the predicted state of operation of engineering systems and an assessment of the possible consequences, you caused by the occurrence of an emergency situation, and recommendations for responding to emergency situations, as well as the formation of management teams of the engineering system in automatic and / or semi-automatic mode with the participation of the operator. 2. The system according to claim 1, characterized in that the central computing module is associated with at least part of the engineering systems selected from the group including: a monitoring, control and dispatching system providing a set of maintenance tools for automatic control, monitoring and optimization of human intervention and administration in order to ensure energy-efficient, economical and safe maintenance of building equipment, a communication system that provides a set of technical means providing information exchange between automated workers of maintenance personnel and automatic systems and made in the form of a telecommunication network based on wired and / or wireless means of communication, a fire alarm system that provides a set of technical means for detecting fires, a fire extinguishing system, providing a complex of technical equipment designed to extinguish a fire, a smoke removal system providing a plex of technical equipment designed to remove smoke, a warning system that provides a complex of technical equipment for informing people, a system of passenger and freight elevators that provides a complex of technical equipment for raising and lowering people and goods, a system of fire elevators and elevators, providing a complex of technical means intended for emergency emergency ascent and descent of people, access control and management system, providing for a complex of technical means designed to control and provide authorized access to or from the premises, buildings, structures, zones and territories, a security alarm system, which provides a set of technical means for detecting unauthorized actions, informing personnel, and automatically submitting control commands to executive devices, a perimeter security system that provides a set of technical means designed to detect unauthorized actions to penetrate into the protected area, informing personnel and for automatically submitting control commands to executive devices, a television surveillance system that provides a set of technical equipment for remote monitoring, a security lighting system that provides a set of technical equipment for technical equipment and security object in the dark, emergency lighting system, providing a set of technical means, designed to control emergency lighting, a system for managing the evacuation of people, which includes a set of technical means designed to alert people and manage life support systems, a physical protection system that provides a set of technical means designed to prevent unauthorized actions, an emergency communication system that provides a set of technical means, for the exchange of verbal information, a system for monitoring the technical condition of construction structures, providing a set of technical means for detecting places of damage and destruction, a system for monitoring and detecting chemical, radiation, explosive and biologically hazardous substances, providing a set of technical means for detecting leaks of radioactive and chemical substances, as well as the presence of explosive and biologically hazardous substances, information security system that provides a set of technical means designed to determine the regime operation of facilities, the system of external monitoring and emergency notification, provides a set of technical means for detecting and warning about the threat of the emergence and occurrence of an emergency. 3. The system according to claim 1, characterized in that the central computing module includes a database of current operating parameters, a database of trending operating parameters, a trend extrapolation unit, a modeling and determination unit for the calculated values of operating parameters, a database of calculated parameters, a comparison unit, a threshold device, unit for modeling and determining the consequences of emergency situations and response recommendations, a unit for generating and transmitting messages and control commands, a control unit, with the first output of the engineering unit systems is connected to the input of the unit for collecting and processing work parameters, the second output of the block for engineering systems is connected to the input of the block for modeling work and determining the calculated values of the parameters, the first output of the block for collecting and processing work parameters is connected to the database of trending parameters, the second output of the block for collecting and processing operation parameters is connected to the database of current parameters, the output of the unit for modeling work and determining the calculated parameters is connected to the database of the calculated parameters, the output of the trend database is the parameters are connected to the trend extrapolation unit, the outputs of the trend extrapolation unit, the database of current parameters, the database of calculation parameters are connected to the inputs of the comparison unit, the output of which is connected to the input of the modeling unit and determining the consequences and recommendations for response, the output of which is connected to the input of the formation unit and transmitting messages and control commands, the output of which is connected to the input of the control unit of the engineering system. 4. The system according to claim 3, characterized in that the unit for generating and transmitting messages and control commands, and / or the unit for modeling and determining the consequences and recommendations for response, and / or the unit for modeling the operation of engineering systems and determining the calculated values of the parameters includes a geographic information system . 5. The system according to claim 3, characterized in that the communication lines of the functional blocks are either wired communication lines, or wireless communication lines, or a combination of wired and wireless communication lines.