BG3095U1 - System for controlling an electrical installation - Google Patents

Abstract

The utility model relates to a system for controlling an electrical installation and finds application in everyday life. The system for controlling an electrical installation has to each separate circuit of the installation inputs for mains supply (5), as to each input for mains supply (5) there is a sensor (1) for measuring the electric current. Each sensor (1) is connected to an analog-to-digital converter (2) for converting the signal from the sensor (1) into digital form. An electromagnetic switch (3) is connected to each sensor (1), which interrupts the flow of electric current through the electric circuit in which it is connected and controlled by a control unit (7) by means of a driver (4). The analog-to-digital converters (2) are connected to the control unit (7). The control unit (7) has a bidirectional connection with an amplitude-frequency converter (8), a calculation module (9), a threshold memory module (10), a communication module (11) and an electronic dashboard (15) with a local interface for controlling the system. The communication module (11) is connected to a database server (12), which is connected via the Internet to an electronic device (13) with a user interface for controlling the system. A power supply unit (16) is provided with the system. In one embodiment of the system for controlling an electrical installation, at least one mobile device (14) with a system control application is connected bidirectionally to the communication module (11).

Description

Field of technology

The utility model refers to a control system for electrical installation and is used in everyday life.

BACKGROUND OF THE INVENTION

Short-circuit protection of an electrical installation is a very important aspect in the supply of electricity, as it can prevent fires and explosions in homes. This determines the use of fuses, and nowadays - circuit breakers. The network is restored by manually switching a fuse. For some subscribers, operating the fuses is still inconvenient for various reasons. Often the electrical panel is located high in the homes. Another reason is ignorance of the function of the panel and fuse, hence the resumption of the supply of much-needed electricity for everyday life is impossible. The facilitation of the persons connected with the installation of an electrical panel is also possible by installing fuses with programmable maximum current.

US6285917e discloses a power system protection and control system comprising mains inputs, a plurality of protection controllers comprising an analog-to-digital converter and a digital processor connected to a local interface. The system has a control unit with a display connected via a communication module via the Internet with a user interface.

The known system has a complex structure and cannot detect early leaks on old cables and sockets.

Technical essence of the utility model

The task of the utility model is to create a control system for electrical installation, which has increased reliability and a high level of safety, to ensure accurate diagnostic information, to detect leaks on old cables and sockets, as well as to detect improper connection of large power and load of wires and contacts in a given circuit of the installation.

The task is solved by a control system of an electrical installation, including inputs for mains power supply and analog-to-digital converters connected to a local interface for system control. The system has a control unit connected via a communication module via the Internet with a user interface for system management.

According to the utility model, the analog-to-digital converters are mounted to a separate circuit of the electrical installation, each analog-to-digital converter being connected to a sensor and a control unit. An electromagnetic switch connected to a driver is provided for each individual circuit of the electrical installation, whereby the control unit is connected to each driver. Each of the sensors is connected to the corresponding electromagnetic switch from the separate circuit of the electrical installation. The control unit has a two-way connection with an amplitude-frequency converter, a calculation module, a memory module for threshold values, the communication module and the local interface for system control. The communication module is connected to a database server, which is connected via the Internet to the user interface for system management. The system is equipped with a power supply.

In one embodiment of the electrical installation control system, at least one mobile device with a system control application is connected to the communication module in both directions.

The system allows precise monitoring and control of each circuit of the electrical installation by measuring electrical current, detecting leaks, short circuits and signaling to the user which of the electrical circuits is in emergency mode. Because electrical current measurement data is collected from multiple sensors, it is possible to send it over the Internet to a database. This provides the opportunity for persons involved in the maintenance of the electrical installation to receive diagnostic information. This information can be used to find problems

4217 Descriptions to certificates for registration of utility models № 02.2 / 28.02.2019 such as network congestion in certain periods of the day, improper operation of the installation, localization of a problem in the installation.

Explanation of the attached figure

In more detail, the utility model is illustrated by the attached figure, in which: figure 1 shows a block diagram of the system.

Examples of implementation of the utility model

As can be seen from the attached figure, the control system of the electrical installation has to each individual circuit of the installation inputs for mains supply 5, and to each input for mains supply 5 there is a sensor 1 for measuring the electric current. Each sensor 1 is connected to an analog-to-digital converter 2 to convert the signal from the sensor 1 into a digital form. An electromagnetic switch 3 is connected to each sensor 1, which interrupts the flow of electric current through the electrical circuit in which it is connected and controlled by control unit 7 by means of driver 4. The analog-to-digital converters 2 are connected to control unit 7. Control unit 7 has a two-way connection with an amplitude-frequency converter 8, a computing module 9, a memory module for threshold values 10, a communication module 11 and a local interface 15 for controlling the system. The communication module 11 is connected to a database server 12, which is connected via the Internet to an electronic device 13 with a user interface for system management. A power supply unit 16 is provided to the system.

In one embodiment of the electrical installation control system, at least one mobile device 14 with a system control application is connected to the communication module 11 in both directions.

Application of the utility model

The system works as follows.

The presence of mains voltage in the installation through the mains power input 5 generates a signal for switching on the power supply unit 16. Upon receipt of this signal, the power supply unit 16 provides supply voltages for all modules of the system. The control unit 7 allocates RAM to the buffer memory and generates a switching signal to each electromagnetic switch 3. In this way, the system is set to operating mode.

Once the system has entered the operating mode, the control unit 7 begins to send requests for measuring electric current to each of the sensors 1 located on the individual electrical circuits. The analog-to-digital converters 2 measure the electrical voltage from the current sensors 1, which is proportional to the measured current from the sensor 1. The voltage value is converted to at least a 10-bit integer from a decimal number system and sent to the control unit 7. This number corresponds to the measured current, but does not yet assign the unit of measurement for electric current - Ampere.

The control unit 7 sends the measurement data, which are in the form of integers from the decimal number system to the calculation module 9, which converts them from an immeasurable decimal integer into a number corresponding to the measured current with a unit of Ampere. This data is sent by the control unit 7 to the memory module for threshold values 10 and is read by the amplitude-frequency converter 8. The amplitude-frequency converter 8 checks step by step each of the measured currents. The check consists in determining whether any of the measured electric currents exceeds the set threshold value in the memory module for threshold values 10. When a high value of the electric current is detected, the duration of the load is also checked, which is also stored in the module with threshold memory 10.

After each conversion, the amplitude-frequency converter 8 returns a positive or negative value to the control unit 7, where:

• the value is negative when the amplitude thresholds are not exceeded or if any value is exceeded, but for a time shorter than the duration threshold

4218 Descriptions to certificates for registration of utility models № 02.2 / 28.02.2019 (it is assumed that the load is accidental);

• the value is positive when in a separate electrical circuit, sensor 1 has made a measurement that exceeds the given threshold in amplitude and threshold in duration.

In case the value is negative, the control unit 7 continues its work by collecting measurements from the analog-to-digital converter 2 and subsequent operations with the amplitude-frequency converter 8.

In case the value is positive, the control unit 7 undertakes to turn off the respective electromagnetic switch 3, in the electrical circuit of which the measured current is. This is done by interrupting the supply of voltage to the driver 4 of the corresponding solenoid switch 3. This operation must be performed immediately to maintain the integrity of the electrical installation. In addition to the rapid opening of the electrical circuit, the control unit 7 must display information in which electrical circuit the problem has occurred. This is done by sending the status information of the electromagnetic switches 3 to an electronic board 15 with the local interface, which visualizes the status of the electromagnetic switches 3 and the user can see where there is a problem in the electrical installation.

After the control unit 7 has responded to the alarm level and by interrupting a circuit and visualizing which circuit it is, it continues to collect and check the data from the other sensors 1. When it goes around all sensors 1 it sends a data array to the communication module 11, namely:

• time and date of the event;

• system identification number;

• identification number of each sensor 1 and its corresponding electromagnetic switch 3;

• measured values of the electric current for each separate circuit of the installation;

• values for the status of each solenoid switch 3.

The communication module 11 connects to the Internet wirelessly. The created data packet is sent to a server with database 12, where it is stored and the information is distributed in appropriate types of fields - numeric, alphanumeric, etc. The database, which is formed over time, can be used to monitor in which installation and which electromagnetic switch 3 has generated an event.

In the event of an event, in addition to notification via an electronic board 15 with a local system management interface, the subscriber can monitor the information through his mobile device 14 with a system management application. Electromagnetic switches 3 can be switched on or off via it.

The electronic device 13 with a user interface for system management allows registration of new systems, viewing and processing of events generated by the systems stored in the database server 12.

Claims (2)

Claims 1. A control system for an electrical installation comprising inputs for mains supply and analog-to-digital converters connected to a local system control interface, a control unit connected via a communication module via the Internet to a system control user interface in that the analog-to-digital converters (2) are mounted to a separate circuit of the electrical installation, each analog-to-digital converter (2) being connected to the control unit (7) and a sensor (1), as to each separate circuit of the electrical installation. the electrical installation provides an electromagnetic switch (3) connected to the driver (4), where the control unit (7) is connected to the drivers (4), and each of the sensors (1) is connected to the corresponding electromagnetic switch (3) from the individual circuit of the electrical installation, as the control unit (7) has a two-way connection with an amplitude-frequency converter (8), a calculation module (9), a module with a memory for values (10), the communication module (11) and an electronic board (15) with a local system management interface, wherein the communication module (11) is connected to a database server (12) which is connected to the electronic device (13) s 4219 Descriptions to utility registration certificates № 02.2 / 28.02.2019 the user interface for system management, and the system is equipped with a power supply unit (16). Electrical installation control system according to claim 1, characterized in that at least one mobile device (14) with a system control application is connected to the communication module (11) in a bidirectional direction.