RU157791U1 - OFFLINE FIRE EXTINGUISHING INSTALLATION - Google Patents

Abstract

1. Autonomous fire extinguishing installation, comprising at least one extinguishing aerosol generator with an electric initiator, a detector and a battery of galvanic cells, characterized in that the installation is additionally equipped with a first signal device connected to a battery of galvanic cells and a first output of the detector, and a second signal device which is connected to the second output of the detector and the controller, which is connected via a breaker to the third output of the detector, the fourth output of the detector being Inonii with a battery of electrochemical cells, the battery cells and extinguishing aerosol generator with elektroinitsiatorom placed in the first installation package, and the first signaling device, the second signaling device, and the chopper controller installed in the second housing ustanovki.2. An autonomous fire extinguishing installation according to claim 1, characterized in that the detector is made in the form of a thermal cable. 3. The stand-alone fire extinguishing installation according to claim 1, characterized in that the first signaling device is made in the form of an LED and a buzzer. 4. An autonomous fire extinguishing installation according to claim 1, characterized in that the first signaling device is made in the form of an LED. The stand-alone fire extinguishing installation according to claim 1, characterized in that the first signaling device is made in the form of a buzzer. 6. The autonomous fire extinguishing installation according to claim 1, characterized in that the second signaling device is made in the form of two LEDs of different colors. An autonomous fire extinguishing installation according to claim 1, characterized in that the first and second buildings are made of dielectric material. Standalone mouth

Description

The utility model relates to fire extinguishing systems and is intended to detect fire sources, the subsequent initiation of fire extinguishing means and fire extinguishing mainly in closed and semi-closed volumes.

Automatic fire extinguishing systems are known from the prior art (copyright certificate 1546087, A62C 35/04, 1990) comprising fire detection units, fire extinguishing devices, initiation units and means for connecting the devices to each other. The main disadvantages of this system are its conditional autonomy associated with the need for periodic monitoring of fire extinguishers and locking and starting mechanisms, as well as a lower fire extinguishing ability compared to aerosol fire extinguishing devices.

These disadvantages are partially eliminated in a fire extinguishing device containing a device that generates a fire extinguishing agent in a combustion mode, a fire detection unit and the use of a fire extinguisher (GB, 2028127, A62C 13/22, 1980). However, this technical solution has insufficient efficiency, primarily due to the relatively low fire extinguishing ability of gaseous products of combustion, which act primarily as inert diluents that reduce the oxygen concentration below the combustibility limit. Fire detection units and the use of fire extinguishers have a large inertia.

The closest technical solution is the device (RU, No. 104467, A62C 35/00, 2010) of an automatic fire extinguishing installation, comprising at least one extinguishing aerosol generator, a thermal ignition detection sensor and an electric start source. According to the proposed device, a thermal cable consisting of two or three conductors was used as a thermal sensor, and a battery of galvanic cells was used as an electric trigger source. The disadvantages of the described device is the lack of the possibility of operational remote monitoring of the state of the battery and the readiness of the installation for operation, as well as the lack of an alarm signal, which leads to a decrease in the reliability and efficiency of fire fighting.

The objective of the utility model was the creation of an autonomous fire extinguishing installation, which would not contain the above disadvantages.

The technical result of this utility model is to increase the reliability of the installation for long (at least 10 years) operation due to the creation of a fire extinguishing installation with full autonomy with the ability to periodically remotely monitor the state of all elements of the electrical circuit, including a battery of galvanic cells, thermal cables, contact cables groups (connectors) and connecting wires. The installation promptly gives a signal of operation, warning of a malfunction in the protected object and minimizing the consequences of a fire.

The technical result is achieved in that an autonomous fire extinguishing installation includes at least one extinguishing aerosol generator with an electric initiator, a detector and a battery of galvanic cells. Additionally, the installation is equipped with a first signal device connected to a battery of galvanic cells and a first output of the detector, and a second signal device. The second signal device is connected to the second terminal of the detector and the controller, which is connected via a breaker to the third terminal of the detector, while the fourth terminal of the detector is connected to a battery of galvanic cells. A detector, a battery of galvanic cells and a fire extinguishing aerosol generator with an electric initiator are installed in the first building of the installation. The first signaling device, the second signaling device, the controller and the chopper are installed in the second installation housing.

Preferably, in a stand-alone fire extinguishing installation, the detector was made in the form of a thermal cable.

Preferably, in a stand-alone fire extinguishing installation, the first signal device was in the form of an LED and a buzzer.

Preferably, in a stand-alone fire extinguishing installation, the first signaling device is in the form of an LED.

Preferably, in a stand-alone fire extinguishing installation, the first signal device was in the form of a buzzer.

Preferably, in a stand-alone fire extinguishing installation, the second signaling device is made in the form of two LEDs of different colors.

Preferably, in a stand-alone fire extinguishing installation, the first and second bodies are made of dielectric material.

It is preferable that in an autonomous fire extinguishing installation, ABS plastic be used as the dielectric material of the first and second housing.

Subsequently, the claimed technical solution is illustrated by a detailed description of a specific but not limiting present solution, an example of its implementation, and the attached drawing.

The stand-alone fire extinguishing installation contains a fire extinguishing aerosol generator 1 with an electric initiator, a detector 2 and a battery 3 of galvanic cells 3. The installation is equipped with a first signal device 4 connected to a battery 3 of galvanic cells and a first output of the detector 2. The installation is also equipped with a controller 5 and a second signal device in series 6. The second signaling device 6 is connected to the second output of the detector 2, and the controller 5 through a chopper 7 is connected to the third output of the detector 2. Four the first output of the detector 2 is connected to a battery 3 of galvanic cells. A battery of 3 galvanic cells and a generator 1 of a fire extinguishing aerosol with an electric initiator are installed in the first building 8 of the installation. The first signal device 4, the second signal device 6, the controller 5 and the chopper 7 are installed in the second installation housing 9.

The detector 2 is preferably made in the form of a segment of a thermal cable of a given length with a response temperature from 54 to 180 ° C. The thermal cable is located inside the protected object in areas of possible fire (cable power inputs, wiring harnesses, etc.). When the polymer insulation of a thermal cable is heated to a predetermined critical temperature, it melts and closes current-carrying conductors. As a result of this, the electric power supply circuit of the electric initiator closes, it operates and starts the generator 1 of the extinguishing aerosol.

A fire extinguishing aerosol generator 1 with an electric initiator, a battery of 3 galvanic cells are placed inside the plastic first housing 8 of the installation. The material of the first housing 8 is made of ABS plastic, for example, grades AX 4000 or ABS 1434, which is a dielectric and allows you to freely place a fire extinguishing aerosol generator 1 with an electric initiator and a battery of 3 galvanic cells near live electrical components.

The first signal device 4 can be made either in the form of any light element (incandescent lamp, or LED), or in the form of an audio signal - a buzzer, it is also possible to perform in the form of an LED and a buzzer. It is preferable that the LED of the first signaling device has a red light, since for humans, this is always a color of danger.

The second signal device 6 can be made in the form of two light elements (incandescent lamps or LEDs), for example, in the form of two green and yellow LEDs, and can also be made in the form of a single LED that changes color from green to yellow under the control of controller 5 .

The first signaling device 4, the second signaling device 6, the controller 5 and the chopper 7 are installed in the second housing 9. The first signaling device 4, the controller 5 and the chopper 7 perform the function of monitoring the electrical circuit, including the detector 2, the fire extinguishing aerosol generator 1 with the electric initiator and the battery 3 galvanic cells. The second signaling device 4 is turned on only when a fire occurs and the installation is triggered. The second housing 9 may have any configuration. It can also be made in the form of a panel, on the front side of which there is a breaker button 7, the first signaling device 4 is a green LED (“ready”) and the second signaling device 6 is a red LED (“fire”). On the back of the second housing 9, a controller 5 and other elements of the electrical circuit are installed. For example, as a controller 5, a controller of type KR1171SP 7.3 can be used, which allows you to change the color of the green LED (“ready”) to yellow (“attention malfunction”) when the voltage at the terminals of the battery 3 of the galvanic cells drops below 7 V, which indicates her discharge. On the rear side of the panel, wires are fixed for connection with a detector 2 (thermal cable), a battery 3 of galvanic cells (for example, a 6LR61 battery) and a generator 1 of a fire extinguishing aerosol with an electric initiator (for example, an electric initiator type EI-2T). All electrical connections are made using connectors and heat-resistant wires. The second housing 9 can be installed either directly on the outer surface of the protected object, or remotely on the console of a dispatcher, driver or driver.

Installation works as follows. The proposed installation works in two modes.

The first mode is the mode of monitoring the state (readiness) of the plant’s performance is carried out periodically at least 1 time per quarter. The control mode is carried out by pressing the button of the chopper 7. In this case, the circuit is closed and the signal from the battery 3 of galvanic cells is supplied to the controller through the detector 2. The controller 5 supplies a signal to the second signaling device 6. A green LED of the second signaling device 6 means that the installation is in working condition, that is, the battery 3 of the galvanic cells has sufficient charge to operate the installation and the tested electrical network is in working condition. If the voltage of the battery 3 of the galvanic cells does not match, the controller 5 gives a signal and the yellow LED of the second signaling device 6 lights up. In this case, it is necessary to replace the battery of 3 galvanic cells.

The second mode of operation of the installation - fire extinguishing mode is as follows. In normal mode, in the absence of fire sources, the electric circuit, including the detector 2, the battery 3 of the galvanic cells, and the generator 1 of the fire extinguishing aerosol with the electric initiator is open and does not consume electricity. If a fire occurs in the protected volume and the temperature rises above critical, for example, for a ТС-220 thermal cable, the critical temperature is 105 ° C, the insulating coating on the conductors of detector 2 is destroyed and the above described electrical circuit is closed. In this case, the current from the battery 3 of the galvanic cells causes the electric initiator to start the fire extinguishing aerosol generator 1. The extinguishing aerosol generator 1 releases an aerosol suppressing a source of ignition. At the same time, the circuit of the first signaling device 4 is activated and the red LED on the second body 9 lights up and / or an audible signal is activated - a buzzer.

After the operation of the installation, the detector 2 is replaced, the extinguishing aerosol generator 1 with the electric initiator or the entire first housing 8.

As can be seen from the above description, all the essential features are in a causal relationship with the claimed technical result. Placing the installation in two separate buildings allows you to protect the elements of the installation from external adverse effects and maintain the operability of the elements, and therefore increase the reliability of the installation as a whole.

Claims (8)

1. Autonomous fire extinguishing installation, comprising at least one extinguishing aerosol generator with an electric initiator, a detector and a battery of galvanic cells, characterized in that the installation is additionally equipped with a first signal device connected to a battery of galvanic cells and a first output of the detector, and a second signal device which is connected to the second output of the detector and the controller, which is connected via a breaker to the third output of the detector, the fourth output of the detector being Inonii with a battery of electrochemical cells, the battery cells and extinguishing aerosol generator with elektroinitsiatorom placed in the first installation package, and the first signaling device, the second signaling device, and the chopper controller installed in the second installation package. 2. Autonomous fire extinguishing installation according to claim 1, characterized in that the detector is made in the form of a thermal cable. 3. The stand-alone fire extinguishing installation according to claim 1, characterized in that the first signaling device is made in the form of an LED and a buzzer. 4. The stand-alone fire extinguishing installation according to claim 1, characterized in that the first signaling device is made in the form of an LED. 5. Autonomous fire extinguishing installation according to claim 1, characterized in that the first signal device is made in the form of a buzzer. 6. Autonomous fire extinguishing installation according to claim 1, characterized in that the second signaling device is made in the form of two LEDs of different colors. 7. Autonomous fire extinguishing installation according to claim 1, characterized in that the first and second buildings are made of dielectric material. 8. Autonomous fire extinguishing installation according to claim 7, characterized in that ABS plastic is used as the dielectric material of the first and second buildings.