RU74249U1 - ELECTRICAL INSTALLATION CONTROL AND PROTECTION DEVICE (OPTIONS) - Google Patents

Abstract

The device for monitoring and protection of electrical installations can be used to control current, insulation resistance of the electrical network and protect motors, generators, transformers and other electrical installations in the event of emergency conditions. In all versions, the device contains current sensors installed in the phases of the supply network of the electrical installation, an electronic current controller, an electromagnetic contactor included in the supply network of the electrical installation, a start-up alarm device, an alarm device, and control circuits for the corresponding alarm system. The main unit of the electronic controller is a microprocessor. The microprocessor is connected to current sensors, a memory unit, an alarm circuit, a trigger alarm control circuit, an insulation resistance measurement unit, a digital input circuit, an electronic time unit, and through an electronic key with an electromagnetic contactor. The operation of the electronic controller is controlled from the control panel of the dispatcher, made on the basis of the second microprocessor (first and third options). Communication between microprocessors is carried out using elements of wireless optical communication. It is possible to control the operation of the electronic controller using a personal computer via the communication interface (second option). Information about the operating mode of the electrical installation, emergency shutdowns is displayed on the digital display of the dispatcher's control panel or on the screen of a remote personal computer. The device promptly notifies of emergency conditions by means of an alarm, about the time and

Description

The utility model relates to the field of electrical engineering, and more specifically to relay current protection of three-phase AC electrical installations and can be used to control current, insulation resistance of the electrical network and protect electric motors, generators, transformers and other electrical installations in the event of emergency conditions.

The prior art device for protecting electrical installations from operational overloads according to the application for the invention No. 92006429, publ. 1996.02.20. It is designed to protect electrical installations from operational overloads by a drop in insulation resistance, overheating temperature, overcurrent consumption and underload current. The device contains sensors of monitored parameters, a rectifier, a delay unit, logical elements AND and OR, settings of the limit values of the monitored parameters, comparators, an indication unit and an actuator for switching off the power supply circuits of an electrical installation in emergency conditions. The device is characterized by minimally short hardware circuits for converting information from sensors of controlled parameters, so it allows you to quickly protect the electrical installation when operating modes deviate. However, the functionality of this known device is limited, because the display unit records only the fact of violation of the operating mode and does not display current information about the operating mode, causes of accidents, the number of emergency shutdowns, the magnitude of operational violations.

Known controller diagnostics and protection according to the patent of the Russian Federation for invention No. 2256993. This device uses a microprocessor-based electrical installation protection system. The controller contains an electronic unit and a control and programming panel. The electronic unit includes an analog-to-digital converter, the inputs of which receive signals from the galvanic isolation unit and preliminary scaling of the input signals in the form of current and voltage, a microprocessor, a clock frequency generator, a frequency divider, a non-volatile memory unit, a non-volatile clock, an executive relay, and an indicator. A clock generator provides a microprocessor with a clock frequency and, through a frequency divider, an analog-to-digital converter. The control and programming panel contains a second microprocessor, a keypad and an indicator. Communication between microprocessors is via an interface. The advantage of the controller is that it allows you to diagnose

a significant number of monitored parameters and to carry out relay protection of electrical installations during emergency conditions caused by a power outage, a prolonged overload, a short circuit in an electrical installation, inter-turn short circuit, phase imbalance, excess open circuit current, voltage drop or overvoltage, etc. In this regard, the controller consists of many blocks and elements and operates on a complicated program. In addition, the device according to patent No. 2256993 does not control such a parameter as the insulation resistance of the electrical network. A decrease in insulation resistance, as is known, leads to the danger of electrical breakdowns, violation of tightness, damage and, as a result, to emergency operation of the electrical installation.

There is also a device for monitoring and protection of electrical installations according to the patent of the Russian Federation for utility model No. 15430. This device is housed in two buildings. In one case, there is a block for processing signals from sensors installed in the phases of the power supply network of the electrical installation, and an executive body (electronic key). In another case, an indication unit is placed. The signal processing unit contains a memory unit including emergency trip counters and a storage circuit for operating settings, and a first microprocessor, which includes a delay unit and comparators. The microprocessor inputs are connected to current sensors and the output of the memory block, and the outputs are connected to the electronic key and the input of the memory block. The electronic key is connected to an electromagnetic contactor, through which the electrical installation is disconnected from the mains. The display unit contains a second microprocessor, to the input of which a button control panel (button keyboard) is connected, and to the output is a digital display, which is equipped with a liquid crystal display with a resolution of two lines of sixteen digits with the provision of information on five pages. In fact, the display unit is the control panel of the dispatcher. In addition, the prototype device contains receiving and transmitting elements of wireless optical communication, due to which information is exchanged between two microprocessors. Transmitting and receiving communication elements are made on infrared emitters and infrared receivers - LEDs. Reading of information occurs at a distance of 5 to 30 cm. The device according to the patent of the Russian Federation No. 1530 allows statistical analysis of emergency situations, control the current operating mode and take the necessary corrective measures when it is rejected. Due to the use of microprocessors it is compact, easy to maintain and provides high reliability of the measured parameters, reliable and fast.

protection. However, the device records only the operation or emergency mode, but not the current information about the operation of the electrical installation. Information about the current electrical installation mode can be obtained only through the control panel by pressing the corresponding keyboard buttons. Information on emergency shutdowns is also displayed on the control panel display. In this case, the device records using the counters of emergency shutdowns only the number of shutdowns, and not the magnitude of the monitored parameters at the time of such shutdowns.

The closest in technical essence and technical result to the claimed device for all three claimed variants of the utility model is a current protection relay according to the RF patent for utility model No. 577523. It is taken as a prototype of the claimed utility model for each of the options.

The current protection relay of Patent No. 57523 contains current sensors installed in the phases of the power supply network of the electrical installation, an electronic signal processing unit from the current sensors (electronic controller), a control panel for the dispatcher and an electromagnetic contactor included in the power supply of the electrical installation. The electronic signal processing unit contains a memory unit, including emergency trip counters and a mode settings storage circuit, a first microprocessor, which includes a delay unit and comparators, an operational display unit, and an actuator (electronic key), made in one housing. The inputs of the first microprocessor are connected to current sensors and the output of the memory unit, and the outputs are connected to the executive body and the input of the memory unit. The dispatcher control panel, mounted in a separate case, contains a second microprocessor connected via an interface to the first microprocessor and connected to it by means of a transmitter / receiver device, a keypad connected to the input of the second microprocessor, and a digital display connected to the output of the second microprocessor. The relay also contains an alarm device, which can be placed on the dispatcher's control panel and made in the form of a bell or in the form of a lamp, which are connected to the microprocessor output via an electronic key (alarm control circuit). The transmitting and receiving device is made electromagnetic, and the microprocessors are interconnected by means of a wired communication line, made in the form of a connecting loop with a probe. The digital display indicator is liquid crystal with a resolution of four lines of twenty bits with the ability to display information on twelve pages.

Like the control and protection device for electrical installations according to the RF patent for utility model No. 15430, the current protection relay according to the RF patent for utility model No. 57523 due to the use of microprocessors is compact, easy to maintain, provides high reliability of the measured parameters, reliable and fast protection. The advantage of the overcurrent protection relay according to patent No. 57523 is that it, with the help of an alarm system, provides prompt notification of emergency conditions and allows you to establish the causes of an emergency shutdown of the electrical installation without using a control panel. The electrical installation is disconnected when the following emergency conditions occur:

- in case of overload or underload current over a specified duration;

- at break of any phase;

- phase imbalance of current more than a given value.

However, the prototype relay does not provide control and protection of the electrical installation with a low insulation resistance of the supply network and during idling of the electrical installation (dry running). Specialists in this field know that a drop in insulation resistance can lead to electrical breakdowns, leakage, damage to the motor winding and, as a consequence, to its emergency operation. In addition, the prototype relay does not record the time and date of the accident.

The objective of the utility model is to expand the range of controlled parameters, expand the functionality of the device and thereby increase the reliability of protection of the electrical installation.

The technical result achieved in solving the problem lies in the prompt notification of the emergency conditions that have arisen with the help of an alarm, accurate measurement of the time and date of the accident and the shutdown of the electrical system in the event of an emergency.

To achieve the specified technical result, the device according to the first embodiment, claimed as a utility model, has in common with the prototype that it contains current sensors installed in the phases of the power supply network of the installation, an electronic current controller, a control panel of the controller, an electromagnetic contactor included in the supply network of the installation, and an alarm device. The electronic controller, as in the prototype, contains the first microprocessor, which includes a delay unit and comparators, contains a memory unit including emergency trip counters and a storage of operating settings, an electronic key connected to an electromagnetic contactor,

and an alarm control circuit. The inputs of the first microprocessor are connected to current sensors and the output of the memory unit. The outputs of the first microprocessor are connected to the input of the memory unit, an electronic key, and an alarm control circuit. The control panel of the dispatcher, made in a separate case, includes a second microprocessor, a digital display connected to the output of the second microprocessor, and a keypad connected to the input of the second microprocessor. In contrast to the prototype, the claimed utility model according to the first embodiment further comprises a trigger alarm device, and the electronic current controller further comprises a trigger alarm control circuit connected to the output of the first microprocessor, an insulation resistance measurement unit connected to one of the phases of the electrical installation power supply network and connected to the input the first microprocessor, a circuit connected to the input of the first microprocessor, and a first electronic time unit connected to the output of the first mic processor and the remote management controller further comprises a second electronic time unit connected to the input of the second microprocessor. The difference is also that the first and second microprocessors are interconnected via wireless optical communication. Transmitting and receiving elements of optical communication can be performed on infrared emitters and receivers of infrared radiation. In special cases, the alarm device can be made in the form of a flashing light indicator, and the trigger device can be in the form of a continuous light indicator, while the indicators are either located on the front panel of the electronic controller housing or on the dispatcher's control panel and connected to the output of the first microprocessor through appropriate alarm control circuits. The digital display indicator is liquid crystal, four-line.

The device for monitoring and protecting the electrical installation according to the second embodiment, by analogy with the prototype, contains current sensors installed in the phases of the supply network of the electrical installation, an electronic current controller, a control unit for inputting and viewing information, an electromagnetic contactor included in the supply network of the electrical installation, and an alarm device. The electronic controller contains a microprocessor, which includes a delay unit and comparators, contains a memory unit including emergency trip counters and a mode settings storage circuit, an electronic key connected to an electromagnetic contactor, and an alarm control circuit. Microprocessor inputs

connected to the current sensors and the output of the memory unit, and the microprocessor outputs are connected to the input of the memory unit, an electronic key and an alarm control circuit. In contrast to the prototype, the utility model according to the second embodiment further comprises a trigger alarm device, and the electronic current controller further comprises a trigger alarm control circuit connected to the output of the first microprocessor, an insulation resistance measurement unit connected to one of the phases of the electrical installation power supply network and connected to the microprocessor input , a circuit connected to the input of the microprocessor, and an electronic time unit connected to the output of the first microprocessor. The functions of the control unit for inputting and viewing information in the second embodiment are performed by a personal computer connected to the microprocessor of an electronic current controller via a communication interface. A personal computer and a microprocessor can be interconnected via an RS-232 or RS-485 communication interface. The alarm device, as in the first version, can be made in the form of a flashing light indicator, and the start-up device can be in the form of a continuous light indicator, with indicators placed on the front panel of the electronic controller housing and connected to the microprocessor output via the corresponding alarm control circuits .

According to the third embodiment, the device for monitoring and protecting the electrical installation, as in the prototype, contains current sensors installed in the phases of the supply network of the electrical installation, an electronic current controller, a control panel for the dispatcher, an electromagnetic contactor included in the supply network of the electrical installation, and an alarm device. The electronic controller contains the first microprocessor, which includes a delay unit and comparators, contains a memory block including emergency trip counters and a mode settings storage circuit, an electronic key connected to an electromagnetic contactor, and an alarm control circuit. The inputs of the first microprocessor are connected to current sensors and the output of the memory unit. The outputs of the first microprocessor are connected to the input of the memory unit, an electronic key, and an alarm control circuit. The control panel of the dispatcher, made in a separate case, as in the prototype, includes a second microprocessor, a digital display connected to the output of the second microprocessor, and a keypad connected to the input of the second microprocessor. In contrast to the prototype, the claimed utility model according to the third embodiment further comprises

a personal computer connected to the first microprocessor of the electronic current controller via a communication interface, and a trigger alarm device. The electronic current controller further comprises a trigger alarm control circuit connected to the output of the first microprocessor, an insulation resistance measurement unit connected to one of the phases of the electrical installation and connected to the input of the first microprocessor, a circuit connected to the input of the first microprocessor, and a first electronic time unit connected to output of the first microprocessor. The control panel of the dispatcher further comprises a second electronic time unit connected to the input of the second microprocessor, while the first and second microprocessors are interconnected via wireless optical communication. The personal computer and the first microprocessor can be interconnected via the RS-232 or RS-485 communication interface. Transmitting and receiving elements of optical communication can be performed on infrared emitters and receivers of infrared radiation. In special cases, the alarm device can be made in the form of a flashing light indicator, and the trigger device can be in the form of a continuous light indicator, while the indicators are either located on the front panel of the electronic controller housing or on the dispatcher's control panel and connected to the output of the first microprocessor through appropriate alarm control circuits. The digital display indicator is liquid crystal, four-line.

The set of essential features that characterize the claimed utility model in each of the options, the applicant is not identified among the known technical solutions, which gives grounds to assert the novelty of the claimed device for each of the options.

Distinctive features in combination with the general features of the prototype are sufficient to achieve the above technical result.

The first microprocessor is designed to process information coming from current sensors, an insulation resistance measuring unit, a circuit, comparing it with the specified mode settings and issuing commands to turn on the alarm and display current information and information about emergency shutdowns on the dispatcher's control panel or personal computer screen . Programming of all the listed functions of the first microprocessor is carried out from the control panel of the dispatcher through the transmitting and receiving optical communication device (first and third options), or using

a service program installed on a personal computer through a communication interface (second option). The trigger alarm control circuit and the trigger alarm device inform about the normal operation of the electrical installation. The presence of an alarm device and alarm control circuits provide the ability to timely take measures to eliminate the emergency. The claimed device in comparison with the prototype with the introduction of additional units and the control of a larger number of indicators expanded functionality and thereby increased the reliability of protection of the electrical installation.

All variants of the claimed utility model are united by a single creative concept and correspond to the requirement of unity of the utility model, since they have the same purpose, they control the same indicators in the same way and are aimed at achieving the same technical result.

The utility model is illustrated by drawings.

Figure 1 presents a block diagram of the inventive device for monitoring and protection of electrical installations according to the first embodiment. Figure 2 is a block diagram of the inventive device for monitoring and protection of electrical installations according to the second embodiment. Figure 3 is a block diagram of the inventive device for monitoring and protection of electrical installations according to the third embodiment.

In the drawings, the letters EI indicate the electrical installation, the letters A, B, C are the phases of the power supply.

The control and protection device of an electrical installation according to the first embodiment comprises an electronic current controller 1 and a control panel of a dispatcher 2, made in separate buildings. The electronic controller 1 (figure 1) contains a first microprocessor 3, the inputs of which are connected to current sensors 4, 5, 6 of a three-phase AC network, a memory unit 7, an electronic key 8 connecting the output of the microprocessor 3 to an electromagnetic contactor 9, an alarm control circuit 10, a trigger alarm control circuit 11, a digital input 12 circuit, an insulation resistance measurement unit 13 connected to one of the phases of the electrical installation, and an electronic time unit 14. The outputs of the memory unit 7 are connected to the inputs of the microprocessor 3, s of the discrete input 12, the insulation resistance measurement unit 13 and the electronic time unit 14. The outputs of the microprocessor 3 are connected to the inputs of the memory unit 7, the alarm control circuit 10, the trigger alarm control circuit 11. The control panel of the dispatcher 2 includes a second microprocessor 15, to one of inputs

of which a button keyboard 16 is connected, and an electronic time unit 17 is connected to another. A digital display 18 is connected to the output of the microprocessor 15. The microprocessors 3, 15 are interconnected via transmitting 19, 20 and receiving 21, 22 optical communication elements. The alarm device and the trigger device are not shown in the drawing. They can be located on the front panel of the case of the electronic controller or on the control panel of the dispatcher and are connected to the output of the first microprocessor through the corresponding alarm control circuits 10, 11.

The control and protection device of the electrical installation according to the second embodiment (Fig. 2) contains the same electronic current controller 1 as in the first embodiment, and a personal computer 23. The electronic controller 1 contains a microprocessor 3, the inputs of which are connected to current sensors 4, 5, 6 three-phase AC network, a memory unit 7, an electronic key 8 connecting the output of the microprocessor 3 to an electromagnetic contactor 9, an alarm control circuit 10, a trigger alarm control circuit 11, a digital input circuit 12, a resistance measurement unit insulation resistance 13, connected to one of the phases of the electrical installation, and the electronic time unit 14. The outputs of the microprocessor 3 are connected to the outputs of the memory unit 7, the digital input circuit 12, the insulation resistance measurement unit 13 and the electronic time unit 14. The inputs of the microprocessor 3 are connected memory 7, alarm control circuit 10, trigger alarm control circuit 11. The microprocessor 3 and the personal computer 23 are interconnected via an interface 24 or 25. The alarm device and device The start alarm is not shown in the drawing. They are located on the front panel of the electronic controller housing and are connected to the output of the first microprocessor through the corresponding alarm control circuits 10, 11.

The control and protection device of the electrical installation according to the third embodiment (Fig. 3) contains an electronic current controller 1, a control panel of the controller 2, made in separate cases, and a personal computer 23. The electronic controller 1 is made in the same way as in the previous versions, and contains a microprocessor 3, the inputs of which are connected to current sensors 4, 5, 6 of a three-phase AC network, a memory unit 7, an electronic key 8 connecting the output of the microprocessor 3 with an electromagnetic contactor 9, an alarm control circuit 10, a control circuit detecting the trigger alarm 11, a digital input circuit 12, the insulation resistance measuring unit 13 connected to one phase

electrical power supply network, and an electronic time unit 14. The control panel of the dispatcher 2 includes a second microprocessor 15, one of the inputs of which has a button keyboard 16, and an electronic time unit 17 is connected to the other. A digital display 18 is connected to the output of the microprocessor 15. Microprocessors 3, 15 are interconnected by transmitting 19, 20 and receiving 21, 22 optical communication elements. The microprocessor 3 and the personal computer 23 are interconnected via an interface 24 or 25. The alarm device and the start-up alarm device are located on the front panel of the electronic controller housing or on the dispatcher's control panel and are connected to the output of the microprocessor 3 through the corresponding signaling control circuits 10, 11.

A utility model for all options is industrially applicable. It can be reused with the achievement of the same specified technical result. All proposed options are tested by the applicant. Devices are operational. Their practical implementation does not cause difficulties for a specialist in this field. In the manufacture of the device uses modern commercially available microprocessors, computers, devices and elements. As current sensors, Hall sensors or toroidal current transformers can be used. For optical communication, IR emitters and IR receivers based on LEDs and photodiodes can be used. It is advisable to use a liquid crystal indicator with a resolution of 4 lines of 20 digits as an indicator of a digital display to increase the amount of information provided. All information can be presented on twelve pages of the display, the sequential switching of which in the forward and reverse order is carried out using the corresponding buttons. The functionality of the electronic current controller, dispatcher control unit and personal computer are determined by the program incorporated in them.

The operation of the device is as follows.

According to the first option (Fig. 1), when programming and reprogramming, the required setting value (values of operating current settings, permissible insulation resistance of the electrical installation, time delays of turning on the protection, time and number of repeated starts, etc.) is set using the keyboard buttons 16 on the digital screen display 18 and is transmitted to the microprocessor 15. This information is transmitted through the transmitting element 20 and the receiving communication element 21 to the microprocessor 3 and then to the memory unit 7. To reset unnecessary information, this

information using the buttons of the keyboard 16 of the control panel of the dispatcher 2 is displayed on the screen of the digital display 18, and then a delete command is issued. Current sensors 4, 5, 6 are installed in the power circuits of three-phase electrical installations (EU) and control the currents flowing through the wires of each of the three phases. Before switching on the EU, the insulation resistance is measured and, if it is normal, the EU is turned on. A continuous glow of a light indicator (for example, yellow light) indicates the normal operation of the EU. The microprocessor 3, under the control of the program embedded in it, compares the information of the operating settings with the information received from the current sensors 4, 5, 6 and from the insulation resistance measuring unit. In the event of an emergency, the microprocessor issues commands to turn off the electromagnetic contactor 9 through the electronic key 8 and to turn on the alarm through the alarm control circuit 10 (for example, in the form of a flashing red light). In addition, through a discrete input circuit 12, one discrete signal is received in the form of a dry contact (idle signal) and the EU is switched off in the event of a dry contact (for example, by a signal from an electrical contact pressure gauge or thermometer). The electrical installation is disconnected when the following emergency conditions occur:

- short circuit;

- idling EU (dry running);

- exceeding the current EU above the rated;

- exceeding the current EU above the maximum allowable;

- the disappearance of one or two phases;

- phase imbalance;

- at break of any phase;

- low insulation resistance.

The electronic time unit 14 fixes the date, time of occurrence of the emergency event. Information about the emergency shutdown (date, time of the occurrence of the emergency event, phase current values at the time of the emergency shutdown of the control unit) is recorded in the memory unit 7. In addition, this information from the microprocessor 3 through the transmitting 19 and receiving 22 communication elements enters the microprocessor 15 of the dispatcher control panel 2 and using the buttons of the keyboard 16 is displayed on the screen of the digital display 18. One control panel 2 can be connected through the transmit-receive elements of optical communication with several electronic current controllers.

According to the second option (Fig. 2), in the control and protection device of the electrical installation, the input of information into the microprocessor 3 and viewing of the parameters is provided using the service program installed on the personal computer 23 through the RS-232 or RS-485 interface. Two communication interfaces make it possible to connect to a personal computer either one electronic current controller or a series of electronic controllers and view information at a remote distance. The operation of the electronic controller in the second embodiment is similar to the operation of the electronic controller in the first embodiment.

According to the third option (Fig. 3), data input, viewing, viewing of emergency outages is carried out using the control panel of the controller 2, and data is also transmitted via the communication interface to the remote personal computer 23. The electronic controller according to the third option is similar to the operation described above for electronic controller according to the first embodiment. Namely, first the required value of the mode settings using the buttons of the keyboard 16 is set on the screen of the digital display 18 and transmitted to the microprocessor 15. This information is transmitted through the transmitting element 20 and the receiving communication element 21 to the microprocessor 3 and then to the memory unit 7. To reset the unnecessary information, this information using the buttons of the keyboard 16 of the control panel of the dispatcher 2 is displayed on the screen of the digital display 18, and then a delete command is issued. Current sensors 4, 5, 6 are installed in the power circuits of three-phase electrical installations (EU) and control the currents flowing through the wires of each of the three phases. Before switching on the EU, the insulation resistance is measured and, if it is normal, the EU is turned on. A continuous glow of a light indicator (for example, yellow light) indicates the normal operation of the EU. The microprocessor 3, under the control of the program embedded in it, compares the information of the operating settings with the information received from the current sensors 4, 5, 6 and from the insulation resistance measuring unit. In the event of an emergency, the microprocessor issues commands to turn off the electromagnetic contactor 9 through the electronic key 8 and to turn on the alarm through the alarm control circuit 10 (for example, in the form of a flashing red light). Information on the operation of the device and on the occurrence of accidents is also displayed on the screen of a personal computer installed at a remote distance. Thus, in all embodiments, the device provides notification of emergency conditions by means of an alarm, measuring the time and date of the accident,

shutdown of the electrical installation in the event of an emergency, and thereby provides reliable protection of the electrical installation.

Claims (14)

1. The control and protection device of an electrical installation, comprising current sensors installed in the phases of the electrical network of the electrical installation, an electronic current controller, a control panel of the dispatcher, an electromagnetic contactor included in the electrical network of the electrical installation, and an alarm device, wherein the electronic controller contains a first microprocessor, the composition of which includes a delay unit and comparators, contains a memory unit including emergency shutdown counters and a storage circuit for operating settings, an electronic key, a connection data with an electromagnetic contactor, and an alarm control circuit; the inputs of the first microprocessor are connected to current sensors and the output of the memory unit, and the outputs of the first microprocessor are connected to the input of the memory unit, an electronic key, and an alarm control circuit; the control panel of the dispatcher, made in a separate case, includes a second microprocessor, a digital display connected to the output of the second microprocessor, and a keypad connected to the input of the second microprocessor, characterized in that it additionally contains a start signaling device, and an electronic current controller contains a trigger alarm control circuit connected to the output of the first microprocessor, an insulation resistance measurement unit connected to one of the phases of the pi network electrical installation and connected to the input of the first microprocessor, a circuit connected to the input of the first microprocessor, and a first electronic time unit connected to the output of the first microprocessor, and the dispatcher control panel further comprises a second electronic time unit connected to the input of the second microprocessor, while the first and the second microprocessors are interconnected via wireless optical communication. 2. The device according to claim 1, characterized in that the transmitting and receiving elements of the optical communication are made respectively on infrared emitters and receivers of infrared radiation. 3. The device according to claim 1, characterized in that the alarm device is made in the form of a flashing light indicator, and the trigger device is in the form of a continuous light indicator, while the indicators are located on the front panel of the electronic controller housing and connected to the output of the first microprocessor through appropriate alarm control circuits. 4. The device according to claim 1, characterized in that the alarm device is made in the form of a flashing light indicator, and the start-up device is in the form of a continuous light indicator, the indicators are located on the control panel of the dispatcher and connected to the output of the first microprocessor through the appropriate circuit alarm management. 5. The device according to claim 1, characterized in that the digital display indicator is liquid crystal, four-line. 6. A device for monitoring and protection of the electrical installation, comprising current sensors installed in the phases of the supply network of the electrical installation, an electronic current controller, a control unit for inputting and viewing information, an electromagnetic contactor included in the supply network of the electrical installation, and an alarm device, the electronic controller comprising the microprocessor, which includes a delay unit and comparators, contains a memory unit, including emergency trip counters and a storage circuit for operating settings, an electronic cl h, coupled with the electromagnetic contactor, and a control circuit as alarm; the microprocessor inputs are connected to the current sensors and the output of the memory unit, and the microprocessor outputs are connected to the input of the memory unit, an electronic key and an alarm control circuit, characterized in that it further comprises a trigger alarm device, and the electronic current controller further comprises a trigger alarm control circuit, connected to the microprocessor output, an insulation resistance measuring unit, connected to one of the phases of the power supply network of the electrical installation and connected to the micro input processor, a circuit connected to the input of the microprocessor, and an electronic time unit connected to the output of the microprocessor, and a personal computer connected to the microprocessor of the electronic current controller via the communication interface was used as a control unit for inputting and viewing information. 7. The device according to claim 6, characterized in that the personal computer and the microprocessor are interconnected via an RS-232 or RS-485 communication interface. 8. The device according to claim 6, characterized in that the alarm device is made in the form of a flashing light indicator, and the trigger device is in the form of a continuous light indicator, while the indicators are located on the front panel of the electronic controller housing and are connected to the output of the first microprocessor through appropriate alarm control circuits. 9. A control and protection device for an electrical installation, comprising current sensors installed in the phases of the power supply network of the electrical installation, an electronic current controller, a control panel of the dispatcher, an electromagnetic contactor included in the power supply network of the electrical installation, and an alarm device, wherein the electronic controller contains a first microprocessor, the composition of which includes a delay unit and comparators, contains a memory unit including emergency shutdown counters and a storage circuit for operating settings, an electronic key, a connection data with an electromagnetic contactor, and an alarm control circuit; the inputs of the first microprocessor are connected to current sensors and the output of the memory unit, and the outputs of the first microprocessor are connected to the input of the memory unit, an electronic key, and an alarm control circuit; the control panel of the dispatcher, made in a separate case, includes a second microprocessor, a digital display connected to the output of the second microprocessor, and a keypad connected to the input of the second microprocessor, characterized in that it further comprises a personal computer connected to the first microprocessor of the electronic controller current through a communication interface, and a trigger device, and an electronic current controller further comprises a trigger control circuit connected to the output of the first microprocessor, an insulation resistance measuring unit connected to one of the phases of the electrical installation power supply network and connected to the input of the first microprocessor, a circuit connected to the input of the first microprocessor, and a first electronic time unit connected to the output of the first microprocessor, and the remote control the controller control further comprises a second electronic time unit connected to the input of the second microprocessor, wherein the first and second microprocessors are interconnected by wireless optical communication. 10. The device according to claim 9, characterized in that the transmitting and receiving elements of the optical communication are made respectively on infrared emitters and receivers of infrared radiation. 11. The device according to claim 9, characterized in that the alarm device is made in the form of a flashing light indicator, and the trigger device is in the form of a continuous light indicator, while the indicators are located on the front panel of the electronic controller housing and connected to the output of the first microprocessor through appropriate alarm control circuits. 12. The device according to claim 9, characterized in that the alarm device is made in the form of a flashing light indicator, and the trigger device is in the form of a continuous light indicator, the indicators are located on the control panel of the dispatcher and connected to the output of the first microprocessor through the appropriate circuit alarm management. 13. The device according to claim 9, characterized in that the digital display indicator is liquid crystal, four-line. 14. The device according to claim 9, characterized in that the personal computer and the microprocessor are interconnected via an RS-232 or RS-485 communication interface.