RU2783451C1 - Safety disconnect device with extinguishing aerosol generator (options) - Google Patents

Abstract

FIELD: electrical engineering and energy.

SUBSTANCE: invention relates to the field of electrical engineering and energy and can be used for prompt emergency shutdown of electrical equipment when exposed to high temperatures, such as fire, as well as overload, overcurrent, short circuit, and electric current leakage. A distinctive feature of the invention is the simultaneous use of a differential phase shutdown mechanism and a zero N shutdown mechanism, a fire-extinguishing aerosol generator (EAG) together with an electric EAG igniter and an initiating temperature-sensitive device (t1) and a shutdown temperature-sensitive device (t2) located in the zone of heat exposure as part of the product. arising during the operation of the fire-extinguishing aerosol generator module (EAG); an initiating temperature-sensitive device (t2) and a tripping temperature-sensitive device (t1) connected in series with each other; EAG module actuation sensor; smoke sensor; a thermal igniter capable of starting the EAG module without starting an electric igniter; a DIN-rail mounting unit, which is a slot for a DIN-rail located on the back of the device case, in which a latch-mount is installed to fix the case on a DIN-rail.

EFFECT: increasing the efficiency of primary fire extinguishing with an increase in the efficiency of preventing the spread of fire in a confined space, in particular, such as an electrical panel, while simultaneously protecting against electric current leaks.

14 cl, 8 dwg

Description

The claimed group of inventions relates to the field of electrical engineering and energy and can be used in the form of a residual current device (RCD) or an introductory residual current device (introductory RCD) of electrical panels to prevent electric shock to a person, operational emergency shutdown of electrical equipment using a differential release without initiation fire extinguishing system or when exposed to high temperatures, for example, in case of fire, while simultaneously initiating an aerosol fire extinguishing system (extinguishing a fire using a fire extinguishing aerosol generator (GOA) while simultaneously opening the line with a differential circuit breaker mechanism. In this case, the device is designed to be mounted on a DIN - rail.

State of the art

Residual current devices (RCDs) are known from the prior art and are installed in an electrical panel on a DIN rail and act as a fuse to protect a person from electric shock in case of electric current leakage. For example, such as molded case RCDs for currents 16-630 A, up to 690 V Schneider Electric, product catalog 2021 (available online at https://download.schneider-electric.com).

However, such well-known solutions do not provide opening of power circuits in the event of a fire in electrical panels and do not have the ability to extinguish fire in electrical panels.

From the patent prior art, a solution is known, which is a pyrotechnic disconnector of an electrical circuit (RU 139706 U1, 04/20/2014). The known disconnector contains a housing in which a conductor and a pyrotechnic charge are located in close proximity or in contact with each other, with a melting temperature of the conductor lower than the combustion temperature of the pyrotechnic charge, while the pyrotechnic charge is started using a thermal cord or from a fire detector.

The technical result, to which the said solution is aimed, is to reliably open the electrical circuit (turn off the power source) in the event of a fire or its threat, which prevents the development of a fire due to a short circuit.

However, the known solution, as well as the above, does not provide the possibility of eliminating the source of ignition. In addition, the functioning of the disconnector when it is activated by a fire detector depends on the performance of external means, which reduces the reliability of its operation.

It should also be noted that the known solution does not have a response time, since for its operation it is necessary to reach the activation temperature of the thermal cord, and the source of this temperature is external, i.e. provided by the source of ignition. Obviously, before this temperature is reached, the fire will spread unhindered, causing damage to surrounding equipment.

To ensure the possibility of not only opening circuits, but also implementing primary automatic fire extinguishing, the prior art uses a combination of opening means and fire extinguishing means, as presented, for example, in the patent source CN 210040091 U, 02/07/2020.

In this solution, the circuit breaker contains the main body, as well as a container with a fire extinguishing agent and a supercharger attached to it. Control of blower actuation and spraying of fire-extinguishing composition is provided when a certain temperature is reached due to a thermal key located on the switch housing.

The known solution eliminates the above-mentioned shortcomings of the prior art in terms of providing the primary fire extinguishing function. Despite this, the known solution has a number of disadvantages, which are as follows.

The complexity and bulkiness of the design of the specified switch prevents its placement in a typical housing of electrical devices for installation on a DIN rail in an electrical panel. At the same time, the placement of means capable of extinguishing a fire source in an electrical panel is critically important, since in a closed limited space of a shield with densely packed electrical modules, fire spreads rapidly, which leads to the emergence of secondary fires due to a short circuit of wires with burnt or melted insulation and irreversible damage to modules.

In addition to the above, the known solution, as well as the one discussed above according to patent RU 139706 U1, does not have a response time, since for its operation it is necessary to reach the activation temperature of the thermal switch, and this temperature is determined by an external source, i.e. the seat of the fire itself. As a result, before the fire extinguishing agent operates, significant damage to the electrical modules located in the electrical panel is possible.

A solution is known from the patent level of technology, which is an autonomous fire extinguishing device with fixation on a DIN rail (utility model patent No. 204767 dated 06/09/21). The known device contains a housing in which the module of the fire extinguishing aerosol generator with a thermochemical initiator is located.

The known solution eliminates the above-mentioned shortcomings of the prior art in terms of providing the primary fire extinguishing function. Despite this, the known solution has a number of disadvantages, which are as follows.

The stand-alone device is made as a separate module and does not have the ability to open power lines, which significantly increases the likelihood of re-ignition of electrical wiring in electrical cabinets and increases the likelihood of electric shock to people, as well as a stand-alone device cannot be initiated by an external control signal and does not generate an information signal about the operation, which does not allow you to combine autonomous devices into groups or inform about the start of the fire extinguishing process.

The technical problem is to overcome the above disadvantages of analogues.

The technical result consists in increasing the efficiency of primary fire extinguishing with an increase in the efficiency of preventing the spread of fire in a confined space, in particular, such as an electrical panel, with simultaneous opening of the electrical circuit, while the described device can open the electrical circuit in case of electric current leaks without initiating an aerosol fire extinguishing system, operating as typical differential circuit breaker for single or three phase connections.

Disclosure of invention

The specified technical result is achieved in a residual current device (RCD) with a fire-extinguishing aerosol generator module (GOA), made in a housing mounted on a DIN rail, containing power electrical terminals placed in the housing for connecting a phase wire, electrical terminals for connecting a neutral wire N, differential mechanism and neutral wire disconnection mechanism N, fire-extinguishing aerosol generator module (GOA), electric igniter GOA, thermal igniter, initiating temperature-sensitive device (t1) and/or smoke detector (d2), configured to start the electric igniter GOA, turning off the temperature-sensitive device ( t2) to control the shutdown of the automatic phase shutdown mechanism and the neutral wire disconnection mechanism, moreover, the input phase A and input zero N terminals are connected through the GOA electric igniter control conductors to the initiating temperature-sensitive device (t1) and / or sensor smoke (d2) and the GOA electric igniter connected to the GOA module, also connected through conductors to the contact group for external start of the electric igniter and the GOA module, and the disconnecting temperature-sensitive device (t2) is located in the immediate vicinity of the GOA module or in the GOA module and through the conductors connected to the mechanism of the differential shutdown of the phase and the mechanism of disconnection of the neutral wire N; in the lower part of the body there are holes for the exit of the aerosol-forming composition, holes for the operation of the initiating temperature-sensitive device (t1), while the thermal igniter is made with the possibility of starting the GOA module without starting the electric igniter, and also with the possibility of triggering the initiating temperature-sensitive device (t1) at a temperature lower than than the temperature of the tripping temperature-sensitive device (t2), determined by the requirements for the operation temperature of the fire-extinguishing aerosol generator (GOA).

In an alternative version of the device, the DIN rail mount is a slot for a DIN rail located on the back side of the device housing, in which a latch is installed to fix the housing on the DIN rail.

In an alternative embodiment, the device contains a temperature-sensitive device (t1) connected via a contact group and wires to the initiating voltage, capable of operating in the event of a fire in the electrical cabinet and, using an electric igniter, initiating the GOA to extinguish the fire in the electrical panel.

Alternatively, the device may contain a fire extinguishing aerosol generator (GOA) activation sensor for generating and outputting a signal to external devices about the fact that the fire extinguishing process has started.

In a preferred embodiment, the initiation unit is made in the form of a thermal igniter and an electric igniter, which in turn is connected to a triggering temperature-sensitive device (t1).

The proposed device is an assembly unit, made in a single housing, and has a functional and structural unity, so it can be claimed as a patent. The housing can be made in the form of standard electrical equipment installed in an electrical cabinet.

The possibility of mounting the proposed device, including GOA with a solid propellant aerosol-forming or gas-forming composition, inside limited rooms with electrical equipment on a DIN rail allows you to suppress fires with high fire-extinguishing efficiency without requiring the installation of additional attachment points.

The execution of the node for mounting on a DIN rail in the form of a slot located on the back side of the device case, in which a latch-mount is installed for fixing the case on a DIN rail, is ergonomic - convenient for installing and removing the device, which makes it possible to install it in various places (including hard-to-reach) switchboards or cabinets, which in turn increases the efficiency of autonomous fire extinguishing in case of fires in electrical equipment.

Taking into account that the DIN rail is widely used for fastening various modular electrical equipment in cabinet-type rooms, and also that the aerosol-forming composition, in comparison with powder, carbon dioxide and foam compositions, has no restrictions on use (in terms of the power of the protected electrical equipment and the presence of voltage) and does not have a negative effect on electrical equipment, the proposed fire extinguishing device can be installed anywhere in the protected object equipped with a DIN rail.

In a developing embodiment, when using the device in three-phase networks, the case additionally contains phase terminals (two more pairs) corresponding to these phases (“B”, “C”) with devices for differential shutdown of these phases connected by a single lever for turning the machine on and off with phase “A” automatic disconnection mechanism and neutral wire disconnection mechanism N.

The specified technical result is also achieved in a residual current device (RCD) with a fire extinguishing aerosol generator module (GOA), made in a housing mounted on a DIN rail, containing power electrical terminals placed in the housing for connecting a phase wire, electrical terminals for connecting a neutral wire N , a phase differential shutdown mechanism and a neutral wire disconnection mechanism N, a fire-extinguishing aerosol generator module (GOA), an electric GOA igniter, a thermal igniter, an initiating temperature-sensitive device (t2) and / or a smoke detector (d2), configured to start an electric GOA igniter, connected with it a thermally sensitive disconnecting device (t1) in series to control the disconnection of the automatic phase disconnection mechanism and the neutral wire disconnection mechanism, moreover, the input phase “A” and the input “zero” N terminals are connected through control conductors to the GOA electric igniter, soe connected with the GOA module, the initiating temperature-sensitive device (t2) and/or the smoke detector (d2) and the tripping temperature-sensitive device (t1), and the tripping temperature-sensitive device (t1) is additionally connected through conductors to the phase differential cut-off mechanism and the neutral wire cut-off mechanism N; in the lower part of the housing there are holes for the exit of the aerosol-forming composition, holes for the correct operation of the initiating temperature-sensitive device (t2) of the smoke sensor (d2) and the shut-off temperature-sensitive device (t1), while the thermal igniter is configured to start the GOA module without starting the electric igniter, and also with the possibility of operation of the initiating temperature-sensitive device (t1) at a temperature lower than the temperature of the switching-off temperature-sensitive device (t2), determined by the requirements for the operation temperature of the fire-extinguishing aerosol generator (GOA).

In an alternative version of the device, the DIN rail mount is a slot for a DIN rail located on the back side of the device housing, in which a latch is installed to fix the housing on the DIN rail.

In an alternative embodiment, the device contains a temperature-sensitive device (t1) connected through a contact group and wires to the initiating voltage, capable of operating in the event of a fire in the electrical cabinet and, using an electric igniter, initiating the HOA to extinguish the fire in the electrical panel.

Alternatively, the device may contain a fire extinguishing aerosol generator (GOA) activation sensor for generating and outputting a signal to external devices about the fact that the fire extinguishing process has started.

In a preferred embodiment, the initiation unit is made in the form of a thermal igniter and an electric igniter connected to it, which in turn is connected to a triggering temperature-sensitive device (t1).

The proposed device is an assembly unit, made in a single housing, and has a functional and structural unity, so it can be claimed as a patent. The housing can be made in the form of standard electrical equipment installed in an electrical cabinet.

The possibility of mounting the proposed device, including GOA with a solid propellant aerosol-forming or gas-forming composition, inside limited rooms with electrical equipment on a DIN rail allows you to suppress fires with high fire-extinguishing efficiency without requiring the installation of additional attachment points.

The execution of the node for mounting on a DIN rail in the form of a slot located on the back side of the device case, in which a latch-mount is installed for fixing the case on a DIN rail, is ergonomic - convenient for installing and removing the device, which makes it possible to install it in various places (including hard-to-reach) switchboards or cabinets, which in turn increases the efficiency of autonomous fire extinguishing in case of fires in electrical equipment.

Taking into account that the DIN rail is widely used for fastening various modular electrical equipment in cabinet-type rooms, and also that the aerosol-forming composition, in comparison with powder, carbon dioxide and foam compositions, has no restrictions on use (in terms of the power of the protected electrical equipment and the presence of voltage) and does not have a negative effect on electrical equipment, the proposed fire extinguishing device can be installed anywhere in the protected object equipped with a DIN rail.

In a developing embodiment, when using the device in three-phase networks, the case additionally contains phase terminals (two more pairs) corresponding to these phases (“B”, “C”) with devices for differential shutdown of these phases connected by a single lever for turning the machine on and off with phase “A” automatic disconnection mechanism and neutral wire disconnection mechanism N.

Further in the description, information is provided regarding the implementation of device options and confirmation of the achievement of the specified technical result.

Implementation of the invention

In accordance with Option 1, the following provides details of an advantageous embodiment of the device, not intended to limit the scope of the requested protection, as defined by the features of the independent claim.

In order to better understand the essence of the patent, the description makes reference to the explanatory drawing (Fig. 1, Fig. 2, Fig. 3, Fig. 4), according to which the external view of the housing with a cut in a single-phase version (Fig. 1), the diagram residual current device (RCD) with a fire-extinguishing aerosol generator in a single-phase version (Fig. 2), the appearance of the housing with a cut in a three-phase version (Fig. 3), a diagram of a residual current device (RCD) with a fire-extinguishing aerosol generator in a three-phase version (Fig. 4);

In a preferred embodiment, the proposed product is mounted in an electrical cabinet on a DIN rail and is an independent device. The product can be used both in single-phase and three-phase networks, for which additional pairs of phase terminals B-B’ and C-C’ are installed in it.

According to figure 1 and fig. 2, in the product case there are: a pair of phase terminals (14-14') and a pair of neutral terminals (13-13'). The device is connected to the device through the phase terminals, the mechanism of the phase differential switch (1), the power wires of the phase, and through the zero terminals N - the mechanism of the zero switch (2), the neutral wire. On the underside of the housing according to Fig. 1 and FIG. 2, outlet holes (7) are made for the exit of the aerosol generated during the operation of the GOA module (12), as well as inlet holes (6) for the correct operation of the initiating temperature-sensitive device (t1) (5) and / or smoke sensor (d2) (17) .

Preferably in the center of the housing, the mechanisms for differential shutdown of the phase and neutral wire N are fixed, and in the side housing, a fire extinguishing aerosol generator (GOA) (12) with an electric GOA igniter (9) and a thermal igniter (22) is fixed. GOA are widespread in the prior art. As an example, the principle of operation of a generator based on the inhibition of chemical processes occurring in a flame by highly dispersed particles (aerosol) of alkali metal salts, released during the combustion of an aerosol-forming charge and capable of being in a suspended state for a long time, can be considered, which ensures the elimination of the focus ignition. At the same time, it is known that during the operation of the GOA, a zone with a significantly elevated temperature (for example, more than 300 °C) is provided around it. This effect is used in a device to increase the efficiency of primary fire extinguishing with an increase in the efficiency of preventing the spread of fire in a confined space, and initiating the phase shutdown mechanism (1) and the zero N shutdown mechanism (2).

In the immediate vicinity of the GOA module (12) in the device case, a tripping temperature-sensitive device (t2) (8) is placed (can be performed with an electrical power and control module - not shown) according to Fig.1 and Fig. 2, which is responsible for generating a signal to turn off the phase differential switch and to turn off zero N in the event of a fire in the electrical panel and the operation of the GOA module (12) using the electric initiator of the GOA (9), the signal for which the initiating temperature-sensitive device (t1) (5) ( can be made with a power supply and control module - not shown) and/or a smoke detector (d2) (17). The choice of distance from the tripping temperature-sensitive device (t2) (8) to the GOA module (12) is selected from the condition that when the GOA module (12) is triggered, the resulting temperature ensures the tripping of the tripping temperature-sensitive device (t2) (8) due to overheating (for example, when 100 °C), thereby closing the tripping temperature-sensitive device (t2) (8) forming a signal to turn off the mechanism for automatically disconnecting the phase and neutral wire N (4). Thus, the term "close proximity" in the framework of this application should be understood as such an arrangement in which the heat from the operating GOA module (12) could trigger the tripping temperature-sensitive device (t2) (8).

Further, as shown in FIG. 1 and FIG. 2, an initiating temperature sensing device (t1) (5) and/or a smoke detector (d2) (17) are housed in the housing. The properties of the initiating temperature-sensitive device (t1) (5) are chosen so that its operation is ensured until the temperature of the operation of the tripping temperature-sensitive device (t2) (8) is reached, and the smoke detector (d2) (17) is activated when a certain temperature appears in the electrical cabinet. concentration of combustion products. For example, the response temperature of the initiating temperature-sensitive device (t1) (5) can be selected in a discrete range (for example, 60°C, 70°C, 80°C) depending on the placement conditions of the device. The initiating temperature-sensitive device (t1) (5) can additionally be equipped with an electrical power supply and control module (not shown) of the GOA electric igniter (9). The initiating temperature-sensitive device (t1) (5) and the smoke sensor (d2) (17) can be connected in parallel, which allows you to start the extinguishing process when any of the sensors is triggered or in series, which implies the operation of the GOA module (12) only when the initiating temperature-sensitive device is triggered (t1) (5) and smoke detector (d2) (17) at the same time. Also, in the GOA module (12), together with the GOA electric igniter (9), a thermal igniter (22) is built in, capable of starting the GOA module (12) on its own when the response temperature is reached.

The proposed device works as follows.

In the normal state of Fig. 1, fig. The 2 phase terminals (14-14') are connected to the differential trip mechanism. This ensures the flow of electric current along the circuit: Terminal (14) - Conductor - Differential trip mechanism (1) - Conductor - Terminal (14’). Also, the zero terminals (13-13 ') are interconnected by the corresponding conductors through the zero disconnection mechanism N (2), ensuring the operability of the power electrical panel. At the same time as indicated, the input terminal (14 phases “A”) and the input terminal (13 neutral “wire” N) are connected through the corresponding control conductors to the initiating temperature-sensitive device (t1) (5) and / or smoke detector (d2) (17) and electric igniter GOA (9) according to Fig. 1 and FIG. 2.

With a three-phase version of the device of Fig. 3, fig. 4 are added circuits for the flow of current in phase “B”: Terminal (14) - Conductor - Differential trip mechanism (15) - Conductor - Terminal (14') and phase “C”: Terminal (14) - Conductor - Differential trip mechanism (16 ) - Conductor - Terminal (14').

When the temperature rises in the electrical panel (ignition of the electrical panel) in which the device is installed to a predetermined critical value determined by the properties of the initiating temperature-sensitive device (t1) (5), (with or without a power supply and control system) (for example, 60 ° C , 70°C, 80°C), heated air enters the body (3) of the device through the hole (6), due to which the initiating temperature-sensitive device (t1) (5) and / or the smoke sensor (d2) (17) connect the electrical GOA igniter (9), (with or without power supply system) with an input terminal (14 phase “A”) and an input terminal (13 “neutral wire” N), thereby ensuring the flow of electric current capable of starting the GOA electric igniter ( 9) and initiate the operation of the GOA module (12).

At the start of operation of the GOA module (12) from the housing (3) through the outlet holes (7), according to Fig. 1 and FIG. 2, the fire-extinguishing aerosol begins to come out in the form of a gaseous mixture, filling the protected volume of the electrical panel and suppressing the combustion of the components of the electrical panel. At the same time, a heating zone is formed around the GOA module (12) up to a temperature of, for example, over 300 °C, acting with its heat flow on the tripping temperature-sensitive device (t2) (8), which, heating up above the temperature of its own overheating operation (for example, more than 100 °C), is triggered, thereby generating a signal for opening the mechanism for automatic shutdown of phase “A” (1) and the mechanism for zero - zero shutdown N (2), and with a three-phase implementation, phase “B” (15) and phase “C” are additionally opened (16) according to FIG. 3 and FIG. four.

Thus, when triggered by the initiating temperature sensing device (t1) (5) and/or the smoke detector (d2) (17), according to FIG. 1 and FIG. 2, as well as Fig. 3 and 4 in case of three-phase execution, during the ignition of the electrical panel, the shield is simultaneously extinguished using the GOA module (12) and phase “A” (1) or phases “A”, “B”, “C” (1, 15, 16) with a three-phase version along the line of phase terminals (14-14') and neutral wire N (2) along the line of zero terminals N (13-13') according to Fig. 1, fig. 2, fig. 3, fig. 4, which can also be attributed to the advantage of the proposed device in comparison with the solutions known from the prior art.

A feature of this device is also the fact that in the event of failure of the operation of the initiating device (t1) (5) or the electric igniter of the GOA (9) or the loss of input voltage, the GOA module will still be started using the thermal igniter (22) (Fig. 1, Fig. 3), taking into account the fact that the response temperature of the thermal igniter is higher than the response temperature of the initiating device (t1) (5), for example, can be 170°C.

It is also important to note that the device contains an input contact group (18) that allows, when a signal is applied to it, to carry out a forced start of the GOA electric igniter (9) using an external device. It is important to note that this contact group also has an inverse function - when several circuit breakers or circuit breakers expansion modules are connected in a line to increase the protected volume, when one of the initiating temperature-sensitive devices (t1) (5) and / or smoke detector (d2) is triggered ) (17) in any of the devices, the other connected devices will receive an input trigger signal and will be forced to start along with the triggered device.

Also, the circuit breaker has a GOA trip sensor (21), which, in turn, sends a signal through the conductors (20) to the contact group (19) for processing the received signal by external control automation.

In the preferred embodiment of the device, a slot is made in the back of the housing (3), in which a latch-mount (23) is installed, designed to fix the housing (3) with the GOA (12) on a DIN rail.

The housing of the device can also be fixed on a DIN rail using a screw connection, however mounting with a DIN rail clip assembly (23) is advantageous as makes it possible to install the device in a wider range of places in a panel or cabinet, which leads to an increase in the efficiency of extinguishing fires.

A distinctive feature of the device is also the ability to turn off the power part of the electrical panel in case of electric current leakage without initiating the GOA module (12) with the possibility of subsequent cocking of the residual current device (RCD) to its original state using the mechanism (4) and continuing to operate the device.

In turn, the use of the GOA module (12) as a means of ensuring the operation of a residual current device (RCD) also accelerates the opening of electrical circuits before a current leakage occurs, thereby preventing the occurrence of secondary fires, since the time required to reach the response temperature of the tripping temperature-sensitive device (t2) (8) due to the operation of the GOA module (seconds) is significantly less compared to if the tripping of the tripping temperature-sensitive device (t2) (8) would be provided by the heat of an external source (i.e. fire seat ).

Thus, only through the joint use of the above means and their operation through these connections, it is possible to achieve the technical result to which the proposed device is directed.

The device can be implemented using means and methods known from the prior art for a specialist, and the analysis of the prior art did not reveal solutions in it that would have all the essential features presented in the formula.

In accordance with option 2, in order to better understand the essence of the patent, references are made in the description to the explanatory drawing (Fig. 5, Fig. 6, Fig. 7, Fig. 8), according to which the external view of the housing with a cut in a single-phase version (Fig. . 5), a circuit of a residual current device (RCD) with a fire extinguishing aerosol generator in a single-phase version (Fig. 6), an external view of the housing with a cut in a three-phase version (Fig. 7), a circuit of a residual current device (RCD) with a fire extinguishing aerosol generator in three-phase version (Fig. 8), as well as a placed residual current device (RCD) with GOA, a set of elements in a single-phase version (Fig. 5, Fig. 6) and a three-phase version (Fig. 7, Fig. 8).

In a preferred embodiment, the proposed product is mounted in an electrical cabinet on a DIN rail and is an independent device. The product can be used both in single-phase and three-phase networks, for which additional pairs of phase terminals B-B’ and C-C’ are installed in it.

According to FIG. 5 and FIG. 6, in the product case there are: a pair of phase terminals (14-14') and a pair of neutral terminals (13-13'). The device is connected to the device through the phase terminals, the mechanism of the phase differential switch (1), the power wires of the phase, and through the zero terminals N - the mechanism of the zero switch (2), the neutral wire. On the underside of the housing according to Fig. 5 and FIG. 6 there are outlets (7) for the exit of the aerosol generated during the operation of the GOA module (12), as well as inlets (6) for the correct operation of the shutdown temperature-sensitive device (t1) (5) and / or smoke sensor (d2) (17) and initiating temperature-sensitive device (t2) (8).

Preferably in the center of the housing, the mechanisms for differential shutdown of the phase and neutral wire N are fixed, and in the side housing, a fire extinguishing aerosol generator (GOA) (12) with an electric GOA igniter (9) and a thermal igniter (22) is fixed. GOA are widespread in the prior art. As an example, the principle of operation of a generator based on the inhibition of chemical processes occurring in a flame by highly dispersed particles (aerosol) of alkali metal salts, released during the combustion of an aerosol-forming charge and capable of being in a suspended state for a long time, can be considered, which ensures the elimination of the focus ignition.

Tripping temperature-sensitive device (t1) (5) (may be provided with power supply and control module - not shown) and/or smoke detector (d2) (17) (with or without control and power system) according to FIG. 5 and FIG. 6, is responsible for generating a signal to turn off the phase differential switch and to turn off zero N in the event of a fire in the electrical panel.

Further, as shown in FIG. 5 and FIG. 6, an initiating temperature sensing device (t2) (8) is housed in the housing. The properties of the initiating temperature-sensing device (t2) (8) are chosen in such a way that its operation is ensured after reaching the response temperature of the tripping temperature-sensitive device (t1) (5) installed next to it and connected in series with it in the electrical circuit and / or the sensor is triggered smoke (d2) (17). For example, the response temperature of the tripping temperature-sensitive device (t1) (5) can be selected in a discrete range (for example, 60°C, 70°C, 80°C) depending on the conditions of the device placement, and the response temperature of the initiating temperature-sensitive device (t2) (8) can be selected in a range (for example, 90°C, 100°C, 110°C). The initiating temperature sensing device (t2) (8) can additionally be equipped with an electrical power supply and control module (not shown). The smoke detector (d2) (17) can be connected to the tripping temperature sensing device (t1) (5) in parallel or in series, or not at all, depending on the task. Also, in the GOA module (12), together with the GOA electric igniter (9), a thermal igniter (22) is built in, capable of starting the GOA module (12) on its own when the response temperature is reached.

The proposed device works as follows.

In the normal state of Fig. 5, fig. The 6 phase terminals (14-14') are connected to the differential trip mechanism. This ensures the flow of electric current along the circuit: Terminal (14) - Conductor - Differential trip mechanism (1) - Conductor - Terminal (14’). Also, the zero terminals (13-13 ') are interconnected by the corresponding conductors through the zero disconnection mechanism N (2), ensuring the operability of the power electrical panel. At the same time as indicated, the input terminal (14 phases “A”) and the input terminal (13 “neutral wire” N) are connected through the corresponding control conductors to the initiating temperature-sensitive device (t2) (8), the disconnecting temperature-sensitive device (t1) (5) and /or a smoke detector (d2) (17) and an electric igniter GOA (9) according to FIG. 5 and FIG. 6. At the same time, the disconnecting temperature-sensitive device (t1) (5) is connected with one of its outputs through the control conductor to the output terminal of phase “A” (14'), and with the second output through the control conductor with the input terminal (13 “neutral wire” N): Output terminal (14') phase “A” - Thermal cut-off device (t1) (5) - Input terminal (13 “neutral” wire N).

With a three-phase version of the device of Fig. 7, fig. 8 the circuits for the current flow in phase “B” are added: Terminal (14) - Conductor - Differential trip mechanism (15) - Conductor - Terminal (14') and phase “C”: Terminal (14) - Conductor - Differential trip mechanism (16 ) - Conductor - Terminal (14').

When the temperature rises in the electrical panel (electric panel fire) in which the device is installed to a predetermined critical value determined by the properties of the tripping temperature-sensitive device (t1) (5), (with or without a power supply and control system) (for example, 60 ° C , 70°C, 80°C), heated air enters the body (3) of the device through the hole (6), due to which the tripping temperature-sensitive device (t1) (5) is activated, which leads to the disconnection of the differential switch of phase “A” and neutral wire N, and with a three-phase implementation, phase “B” and phase “C” are additionally opened according to Fig. 7 and FIG. 8. Exactly the same shutdown of phase “A” or phases “A”, “B”, “C” will occur if the smoke detector (d2) (17) is triggered.

If the fire continues to develop with the power off of devices connected after the residual current device (RCD) with a fire-extinguishing aerosol generator, and a further increase in temperature, the initiating temperature-sensitive device (t2) (8) is activated, as a result of which the electric current briefly begins to flow through the circuit: terminal (14) - Conductor - GOA electric igniter (9) - Initiating temperature sensing device (t2) (8) - Tripping temperature sensing device (t1) (5) - Conductor - Input terminal (13), thereby ensuring a short-term flow of electric current, capable of starting the GOA electric igniter (9) and initiating the operation of the GOA module (12). After initiation of the GOA electric igniter (9), it burns out and finally opens the circuit. - Input terminal (13)

At the start of operation of the GOA module (12) from the housing (3) through the outlet holes (7) according to Fig. 5 and FIG. 6, the fire-extinguishing aerosol starts to come out in the form of a gaseous mixture, filling the protected volume of the electrical panel and suppressing the combustion of the components of the electrical panel.

Thus, upon successive operation of the tripping temperature sensing device (t1) (5) and/or the smoke detector (d2) (17) and the initiating temperature sensing device (t2) (8), according to FIG. 5 and FIG. 6 as well as FIG. 7 and FIG. 8 with a three-phase version, during the ignition of the electrical panel, the shield is simultaneously extinguished using the GOA module (12) and phase “A” (1) or phases “A”, “B”, “C” (1, 15, 16) are opened with a three-phase version along the line of phase terminals (14-14') and neutral wire N (2) along the line of zero terminals N (13-13') according to Fig. 5, fig. 6, fig. 7, fig. 8, which can also be attributed to the advantage of the proposed device in comparison with the solutions known from the prior art.

A feature of this device is also the fact that in case of failure of the operation of the initiating device (t1) (5) or the electric igniter of the GOA (9) or the loss of input voltage, the GOA module will still be started using the thermal igniter (22) (Fig. 5, Fig.7), taking into account the fact that the temperature of operation of the thermal igniter is higher than the temperature of operation of the initiating device (t1) (5), and, for example, may be 170°C.

It is also important to note that the device contains an input contact group (18) that allows, when a signal is applied to it, to carry out a forced start of the GOA electric igniter (9) using an external device. It is important to note that this contact group also has an inverse function - when several power circuit breakers or power circuit breakers expansion modules are connected in a line to increase the protected volume, when one of the initiating temperature-sensitive devices (t1) (5) and / or a smoke detector is triggered (d2) (17) in any of the devices, the other connected devices will receive an input trigger signal and will be forced to start along with the triggered device.

Also, the circuit breaker has a GOA trip sensor (21), which, in turn, sends a signal through the conductors (20) to the contact group (19) for processing the received signal by external control automation.

In the preferred embodiment of the device, a slot is made in the back of the housing (3), in which a latch-mount (23) is installed, designed to fix the housing (3) with the GOA (12) on a DIN rail.

The housing of the device can also be fixed on a DIN rail using a screw connection, however mounting with a DIN rail clip assembly (23) is advantageous as makes it possible to install the device in a wider range of places in a panel or cabinet, which leads to an increase in the efficiency of extinguishing fires.

A distinctive feature of the device is also the ability to turn off the power part of the electrical panel in case of electric current leakage without initiating the GOA module (12) with the possibility of subsequent cocking of the residual current device (RCD) to its original state using the mechanism (4) and continuing to operate the device.

Thus, only through the joint use of the above means and their operation through these connections, it is possible to achieve the technical result to which the proposed device is directed.

The device can be implemented using means and methods known from the prior art for a specialist, and the analysis of the prior art did not reveal solutions in it that would have all the essential features presented in the formula.

Claims (14)

1. Residual current device (RCD) with a fire-extinguishing aerosol generator module (GOA), made in a housing mounted on a DIN rail, containing power electrical terminals placed in the housing for connecting phase wire A, electrical terminals for connecting neutral wire N, generator module fire-extinguishing aerosol (GOA), a mechanism for differential and automatic shutdown of phase A and a mechanism for disconnecting a neutral wire N, an electric igniter GOA, a thermal igniter, an initiating temperature-sensitive device (t1) and / or a smoke detector (d2), configured to start an electric igniter GOA, turning off a temperature-sensitive device (t2) configured to control the shutdown of the differential and automatic phase shutdown mechanism and the neutral wire disconnection mechanism, moreover, the input power electrical terminal for connecting the phase wire A and the input electrical terminal for connecting the neutral wire N through the wire The control units of the GOA electric igniter are connected to the initiating temperature-sensitive device (t1) and/or the smoke sensor (d2) and the GOA electric igniter connected to the GOA module, and are also connected through conductors to the contact group for external start of the electric igniter and the GOA module, and the shutdown the temperature-sensitive device (t2) is located so that it can be triggered by the heat emitted when the GOA module is triggered, and is connected through conductors to the mechanism for differential and automatic shutdown of phase A and the mechanism for disconnecting the neutral wire N; in the lower part of the housing there are holes for the exit of the aerosol-forming composition, holes for the operation of the initiating temperature-sensitive device (t1) and / or smoke sensor d2, while the thermal igniter is configured to start the GOA module without starting the electric igniter, and the initiating temperature-sensitive device is configured to operate when temperature (t1) is lower than the response temperature of the tripping temperature sensing device (t2). 2. The residual current device according to claim 1, characterized in that it additionally contains two pairs of phase terminals: phases B and C, connected to each other and the mechanism of phase A by mechanisms of differential and automatic switching off of phases. 3. The protective shutdown device according to claim 1, characterized in that the aerosol-forming composition is a low-temperature solid fuel composition. 4. The residual current device according to claim 1, characterized in that the smoke sensor contains a control and power module. 5. The residual current device according to claim 1, characterized in that it additionally contains a GOA module actuation sensor connected by conductors to a contact group to generate a GOA module actuation signal for external devices. 6. Residual current device according to claim 1, characterized in that the DIN rail mount is a slot for a DIN rail located on the back side of the device case, in which a latch-mount is installed to fix the case on the DIN rail. 7. The protective shutdown device according to claim 1, characterized in that it contains a sensor for triggering a fire extinguishing aerosol generator (GOA) for generating and outputting a signal to external devices about the fact that the fire extinguishing process has started. 8. Residual current device (RCD) with a fire-extinguishing aerosol generator module (GOA), made in a housing mounted on a DIN rail, containing power electrical terminals placed in the housing for connecting phase wire A, electrical terminals for connecting neutral wire N, differential mechanism and automatic shutdown of phase A and a neutral wire disconnection mechanism N, a fire extinguishing aerosol generator module (GOA), an electric igniter of GOA, a thermal igniter, an initiating temperature-sensitive device (t2) and / or a smoke detector (d2), made with the ability to start an electric igniter of GOA and through conductors connected to the contact group for external start of the electric igniter and the GOA module, while the initiating temperature-sensitive device (t2) is connected in series with the tripping temperature-sensitive device (t1), configured to control the shutdown of the differential and automatic shutdown mechanism phase A and the mechanism for disconnecting the neutral wire N, moreover, the input power electrical terminal for connecting the phase wire A and the input electrical terminal for connecting the neutral wire N are connected through control conductors to the GOA electric igniter connected to the GOA module, the initiating temperature-sensitive device (t2) and /or a smoke sensor (d2) and a thermally sensitive disconnecting device (t1), which is additionally connected through conductors to the mechanism for differential and automatic shutdown of phase A and the mechanism for disconnecting the neutral wire N; temperature-sensitive device (t2) and/or smoke sensor d2 and a shut-off temperature-sensitive device (t1), while the thermal igniter is configured to start the GOA module without starting the electric igniter, and the initiating temperature-sensitive device is configured to tripping at a temperature (t1) lower than the tripping temperature of the temperature-sensitive tripping device (t2). 9. The residual current device according to claim 8, characterized in that it additionally contains two pairs of phase terminals: phases B and C, connected to each other and the mechanism of phase A by mechanisms of differential and automatic switching off of phases. 10. The protective shutdown device according to claim 8, characterized in that the aerosol-forming composition is a low-temperature solid fuel composition. 11. Residual current device according to claim 8, characterized in that the smoke detector contains a control and power module. 12. The residual current device according to claim 8, characterized in that it additionally contains a GOA module actuation sensor connected by conductors to a contact group to generate a GOA module actuation signal for external devices. 13. Residual current device according to claim 8, characterized in that the DIN rail mount is a slot for a DIN rail located on the back of the device housing, in which a latch-mount is installed to fix the housing on the DIN rail. 14. The protective shutdown device according to claim 8, characterized in that it contains a sensor for triggering a fire extinguishing aerosol generator (GOA) for generating and outputting a signal to external devices about the fact of starting the fire extinguishing process.

Images