RU218498U1 - FIRE PROTECTION DEVICE - Google Patents

Abstract

The utility model relates to temperature-sensitive, explosion-proof automatic devices for controlling fire-fighting equipment and alarms. The expansion of the arsenal of fire protection devices used in explosive environments is achieved by creating a device for the specified purpose with additional functionality. The fire protection device contains a housing in which a spring-loaded rod is installed connected to the trigger element. A permanent magnet is installed at the end of the rod, under which an inductance coil is placed, made with the possibility of passing a rod with a permanent magnet through it. The place of the output of the inductor is closed by a lid. The lower part is additionally attached to the body. A board is hermetically installed in the lower part of the case, on which an electrical circuit for communication with the powder fire extinguishing module, an electrical circuit for communication with a control fire protection device, an electrical circuit for communication with the operated equipment are located. All electrical circuits of the board are connected to the output of the inductor. Electrical circuits for communication with the control fire protection device and for communication with the operated equipment contain magnetically controlled sealed contacts. All electrical circuits are designed to transmit signals over a single cable. The exit point of a single cable from the bottom of the housing is sealed.

Description

The utility model relates to fire-fighting equipment, in particular to temperature-sensitive, explosion-proof automatic devices for controlling fire-fighting equipment and alarms. It can be used for fire protection of various objects, including equipment operating in explosive environments. It is applicable in underground conditions of mines and mines, dangerous for gas and coal dust, as well as in explosive areas of premises and outdoor installations.

A pulse starter is known according to the RF patent for utility model No. 35724, A62C 35/00, 2004. The pulse starter contains a housing placed inside the housing, permanent magnets connected by the same poles, fixed on a rod made of non-magnetic material. Permanent magnets are installed with the possibility of interacting with an inductance coil having a frame and located in a magnetically conductive support. A trigger element is located outside the housing. The pulse starter is equipped with a fuse and a cover, while the rod has a head with a through hole and is loaded towards the inductor. The fuse is located in the through hole of the rod head. The trigger element covers the head of the rod and is installed in the housing with the possibility of releasing the head covered by it. The cover is fixed on the frame of the inductor coil. The disadvantage is the limited functionality of the impulse starter, the inability to use it in explosive environments.

A signal-starting device is known according to the RF patent for utility model No. 100412, A62C 37/00, 2010. The device includes a housing made of electrically insulating material, an inductor with an axial channel and electrical leads placed in the housing, a rod with a permanent magnet, a latch and a drive for translational motion stock. The rod is installed coaxially with the coil channel so that the magnet can be moved inside the coil channel along the guide. The guide is made in the form of a sleeve coaxially aligned with the coil channel. The latch is made with the possibility of fastening at the end of the rod. The frame with the central channel is made coaxially with the channel of the inductor. The frame is detachably connected to the body and is made of an electrically insulating material, and the electrical leads of the inductor provide the possibility of forming a short-circuited electrical circuit. The formation of a short-circuited circuit is provided by closing the electrical conductors through the body of the magnet, connected to the terminals of the inductor. The device can be made with the possibility of issuing a signal about its operation, which is its additional function. However, the disadvantage of the device is the impossibility of its simultaneous use for transmitting alarms to a remote station, emergency shutdown of equipment and launching fire extinguishing modules. The disadvantage of this device is the lack of sealing of contacts, which does not ensure the intrinsic safety of the circuit. This does not allow the device to be used in explosive environments.

As the closest analogue to the claimed technical solution, a pulse starter was chosen according to the RF patent for utility model No. 192849, A62C 37/00, 03.10.2019. In the body of the starter, a spring-loaded rod made of non-magnetic material is installed with a thermal trigger fixed at the outer end, and permanent magnets are fixed at its inner end, interconnected by poles of the same name. The starter is made of a material with a shape memory effect. Under the magnets in the magnetic support there is an inductance coil in the form of a torus with a through hole for permanent magnets to pass through it. Under the magnetically conductive support of the inductance coil, an integral assembly is formed, including technological cavities with a contact installed between them, providing a connection between the input and output ends of the connecting wires of the inductor coil and a channel for wires. The wires are designed to provide communication with the fire extinguishing system. Technological cavities and channels for wires are filled flush with the base of the housing with sealant. The base of the case is closed with a lid, and a protective cap is fixed on its neck, covering the head with a thermal trigger. The disadvantage of the pulse starter is its low functionality, which does not provide the versatility of fire protection. In particular, the disadvantage of the proposed solution is the absence of a separate group of contacts for signaling the actuation of the starter. This significantly reduces the information content of the automatic fire extinguishing system in which the proposed starters are used.

The technical objective of the claimed utility model is to expand the arsenal of fire protection equipment used in explosive environments.

The technical result is the implementation of the specified purpose by the utility model.

The technical result is achieved due to the fact that in the fire protection device containing a housing in which a spring-loaded rod is installed, the outer end of the rod, located outside the housing, is connected to the trigger element, at the inner end of the rod, located in the housing, a permanent magnet is installed, under which an inductance coil is placed, made with the possibility of passing a rod with a permanent magnet through it, the place of the output of the inductance coil is closed with a cover, according to the utility model, the lower part is additionally attached to the case, a board is hermetically installed in the lower part of the case, on which an electric circuit for communication with the module is placed powder fire extinguishing, an electrical circuit for communication with a control fire protection device, an electrical circuit for communication with the equipment in operation, the electrical circuits of the board are connected to the output of the inductor coil, the electrical circuits for communication with the control fire protection device and for communication with the equipment in operation contain magnetically controlled sealed contacts, all electrical the circuits are made with the possibility of transmitting signals over a single cable, the exit point of which from the lower part of the housing is sealed.

The arsenal of fire protection devices used in explosive environments is expanding by creating a fire protection device with additional functionality. The use of an enlarged composite case makes it possible to place in it a sealed board with electronic elements functionally connected with the elements in the main body. Installing the board in an additional part of the housing allows you to place it in close proximity to the induction coil. This allows the use of magnetically controlled contacts as part of the electrical circuits of the board, which are triggered by the influence of an electromagnetic field that is induced in the induction coil. The presence of magnetically controlled sealed contacts allows you to generate electrical signals in the electrical circuits of the circuits located on the board. The very presence of three different electrical circuits on the board allows you to expand the functionality of the device. The expansion occurs due to the possibility of automatic control of the powder fire extinguishing module, due to the possibility of automatic signal transmission to the control fire protection device and due to the possibility of automatic shutdown of the equipment in operation when the temperature in the room rises and the trigger element is triggered. Placing the board in a hermetic cavity, making the conclusions of the electrical circuits of the board with the possibility of transmitting signals over a single cable, sealing the cable exit point from the additional lower part of the case make it possible to use the device in explosive environments.

Figure 1 shows a fire protection device.

Figure 2 shows a top view of the bottom of the case.

Figure 3 shows the electrical circuit of the board.

The fire protection device consists of a housing containing the main upper part 1 and an additional lower part 2. In the upper part 1 of the housing there is a trigger element 3, which can be a pulsed thermal starter made of a material with a shape memory effect, or can be made in the form of a ring for manual start. With the help of the trigger element 3, the upper end of the spring-loaded rod 4 is fixed, the rod is in a static state and occupies a spatial position at the top of the housing. At the lower end of the rod 4, located inside the housing, a permanent magnet 5 is fixed, consisting of two parts to form two poles, due to which the magnet 5 has its own magnetic field and when passing through the inductor 6, an EMF occurs. The inductor 6 is located below the permanent magnet 5, mounted on the rod 4, which is in the upper position. The inductor 6 is made in the form of a torus. The output point 7 of the inductor 6 is closed with a cover 8. The upper 1 and lower 2 parts of the body are equipped with flanges 9 for connecting them to each other. The connection of the upper part 1 of the housing with its lower part 2 is carried out with four screws through a hermetic seal in the form of a rubber gasket that repeats the shape of the cover 8. The lower part 2 of the housing is a metal shell, inside which is placed a board 10 made of textolite, filled with high-temperature sealant. The electronic elements of the electrical circuits I, II, III are fixed on the board 10 by soldering, connected to the output of the inductor 6. The electrical circuit I contains a diode V1, a zener diode V2, a resistor R, the outputs (+) (-) of the circuit I are brought out into a single cable 11 and are used to communicate with the powder fire extinguishing module through the junction box. Zener diode V2 and resistor R are used in this circuit to limit the output parameters of the signal to values corresponding to the explosion protection "intrinsically safe electrical circuit". Electrical circuit II contains a diode VD1, magnetically controlled sealed normally closed contacts (reed switches) S1 and S2. The outputs (+K) (-K) of circuit II are brought out into a single cable 11 and serve to communicate through a junction box with the equipment in operation, for example, with a mine conveyor. Electrical circuit III contains a diode VD2, magnetically controlled sealed normally closed contacts (reed switches) S3 and S4. The outputs (+I) (-I) of circuit III are brought out into a single cable 11 and serve to communicate through a junction box with a fire and security control device, for example, VERS, Granite, Astra, etc. Semiconductor diodes V1, VD1, VD2 are used for monitoring the electrical connection between the fire protection device, the powder fire extinguishing module, the fire and security control panel and the equipment in use. Monitoring the integrity of the communication line with the fire protection device is carried out by applying alternating voltage from the receiving and control security and fire control device to the circuits I, II, III circuits. The presence of semiconductor diodes V1, VD1, VD2 ensures one-way current flow in the circuits of the circuits, which is violated in the event of a short circuit or open circuit and is fixed by the fire control panel.

The fire protection device operates as follows.

Install in the trigger starter 3 temperature-sensitive element corresponding to the selected value of the response temperature, for example +47; +72; +93; +110 °С. When the ambient temperature in the protected room rises to the response temperature, the temperature-sensitive element of the trigger 3 changes its position or shape and releases the spring-loaded rod 4 in the upper part 1 of the housing. The magnet 5 fixed at the lower end of the rod 4 passes through the induction coil 6 and produces in her impulse. At the time of the passage of the pulse, an electric current arises in the electric circuit I, a signal is sent through the cable 11 to the junction box and then to the ignition device of the powder fire extinguishing module. Also, when a pulse occurs in the induction coil 6 in the electrical circuits II and III, the circuits break due to the operation of magnetically controlled contacts of sealed normally closed (reed switches) S1, S2, S3, S4. These contacts are located at an angle to the power lines of the electromagnetic field that occurs in the induction coil 6 after triggering the trigger element 3 and lowering the rod 4 with a permanent magnet 5. Due to the electrical circuit and the location of the reed switches S1, S2, S3, S4, the best susceptibility to the impact is ensured. electromagnetic field. The presence of four reed switches, two for each group of contacts, increases the reliability of operation. An open circuit is a signal to turn off the equipment in operation and the appearance of a warning indication on the fire control device. Circuit I generates a signal that starts the powder fire extinguishing module, therefore, the condition for its operation is the formation and transmission of an electrical impulse, which starts the fire extinguishing module. The magnitude of the impulse itself is not large enough to transmit it through three communication circuits, so the work of circuits II and III is built by breaking the circuit. The transmission of signals and impulses is carried out through one cable 11.

Thus, the utility model allows expanding the arsenal of fire protection equipment used in explosive environments by creating a device for this purpose with additional functionality.

Claims (1)

A fire protection device comprising a housing in which a spring-loaded rod is installed, the outer end of the rod, located outside the housing, is connected to the trigger element, a permanent magnet is installed at the inner end of the rod, located in the housing, under which an inductive coil is placed, made with the possibility of passing through of the rod with a permanent magnet; fire protection device and an electrical circuit for communication with the equipment in operation, the electrical circuits of the board are connected to the output of the inductor coil, the electrical circuits for communication with the control fire protection device and for communication with the equipment in operation contain magnetically controlled sealed contacts, all electrical circuits are made with the ability to transmit signals over a single cable , the exit point of which from the lower part of the housing is sealed.

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