FR2706312A1 - Installation for extinguishing fire by delivering an extinguishing fluid - Google Patents

Abstract

Installation for extinguishing in a room (L), comprising a source of fluid (7) with extinguishing property which, under the action of a delivery device (6), communicates with the room (L), and two fire detectors (1, 2) arranged in the room (L) and connected in parallel to an electronic circuit for controlling the delivery device. Application to extinguishing using CO2.

Description

Fire extinguishing installation by sending an extinguishing fluid.

 The present invention relates to fire detection and extinguishing installations. It applies more particularly to extinction by an extinguishing fluid, such as a halon, of carbon dioxide, in the field of fire safety of buildings, for example for automatic extinguishing installations.

 An automatic fire detection and extinguishing installation is known, in which the fire is detected by a detector placed in the room to be protected.

It transmits the information to an electronic “detection-extinction” system which processes it and which supplies a command signal to send C02 to pyrotechnic triggers placed on a C02 bottle, for example, outside the building or cellar.

 Such an installation must be triggered as soon as a fire occurs. But it is just as important, for the safety of people, that it does not go off unexpectedly, without prior alarm inviting to leave the premises. For this purpose, two detectors have been provided mounted in parallel upstream of the electronic system and steps have been taken to send a CO 2 sending command only when the two detectors detect the fire at the same time. Recently, it has been proposed to provide a barrier valve downstream from the source of C02 which authorizes the passage of C02 only when the room to be protected from the fire is free from any human presence, with the major drawback of then put the extinguishing system out of service and with the risk of forgetting to put the barrier valve back in the position allowing the C02 to reach a room to be protected. Despite this, we deplore each year several unexplained emissions of C02, the consequences of which on human life can be serious.

 The invention remedies these drawbacks by an installation which, while being able to be kept in service, makes it possible to practically eliminate untimely CO2 emissions.

 It relates to an extinguishing installation in a room, comprising a source of fluid with extinguishing properties, in particular CO2, which, under the action of a sending device, communicates with the room and two fire detectors arranged in the room and connected in parallel to an electronic circuit for controlling the sending device, characterized in that the electronic circuit comprises, connected respectively to the two detectors, two electronic blocks, the two blocks being connected to the sending device by via an element, called an AND function, which transmits a signal to the sending device only when it receives signals from the two blocks at the same time. If one of the two blocks inadvertently transmits a command signal to send CO2 to the element with AND function, the latter will not transmit it to the sending device, since it has not received the same information from the other block.

The origin of the unexplained emissions of C02 probably comes from faults in the electronics and the connections between the blocks and the sending device.

The installation according to the invention is always operational, except when it breaks down, which is the subject of a signaling, while the installations with a gate valve are sometimes made non-operational, even if they are not in operation. breakdown.

 So that there are as few danger-causing wires as possible downstream of the AND function element, it is advantageous that the line length between the AND function element and the sending device is shorter to that between the element with AND function and the two blocks. In the most completed embodiment, greatly reducing the probability of an accident due to electronics failure, the AND function element is mounted on the very source of fluid. This source constitutes a point of discrimination in the installation. The pipe downstream of the fluid source is very safe, on the one hand, due to its non-electrical nature and, on the other hand, due to the fact that a leak on this pipe does not lead to the release of fluid in the room. Likewise, if the C02 bottle leaks, the fluid does not, for the most part, reach the room, but is released where the bottle is located.

If the bottle is piloting others, the latter are not ordered if the fluid is released outside the pilot bottle. It is essentially the reliability of the electronics that should be improved, while downstream of the bottle we can keep the existing installation.

 If the first line between a first block and the AND function element and the second line between a second block and the AND function element are, over most of their length, distant from each other by so that a localized external disturbance, in particular lightning, acting on one of the lines, does not act on the other line, the distance between the two lines being in particular at least one meter, even if the lightning falls on one line, it spares the other. There is no signal. The AND function element does not transmit a control signal.

 According to a particularly simple and safe embodiment, a conduit places the fluid source in communication with a fluid inlet connection of the sending device and the AND function element comprises two solenoid valves mounted in series on the conduit and excited electrically in parallel by the two blocks. When the first solenoid valve receives a send control signal transmitted by the first block, it lets gas pass from the source of fluid with extinguishing properties into the conduit. However, this gas does not reach the fluid inlet connection of the sending device, unless the second solenoid valve receives a control signal transmitted by the second block.

The sending device then triggers the emission of CO2.

Only the first solenoid valve is permanently subjected to the pressure of the bottle. If it fails, the second solenoid valve, which under normal circumstances is not subjected to any pressure and which, for this reason is very reliable, prevents any passage of gas in the conduit.

In the accompanying drawing, given by way of example
Figure 1 is a diagram of a fire extinguishing installation according to the invention.

 Figure 2 is a partial sectional view of the part of the installation of Figure 1, which is close to the source of fluid.

 The fire extinguishing installation represented in FIG. 1 comprises two smoke detectors 1 and 2 in a room L, for example the room of a building to be monitored.

These two detectors are connected, by lines a and b, respectively to the inputs of two blocks 3 and 4 of an electronic circuit. These two blocks 3 and 4 respectively comprise a fire detection system in series with a fire extinguishing system, not shown in the drawing. The outputs of the two blocks 3 and 4 are connected, by lines c and d, 2 m apart over most of their length, to the two inputs of an element 5 with AND function which is placed on a device for main shipment 6 attached to a main bottle 7 which acts as a source of an extinguishing fluid, such as carbon dioxide. The bottle 7 is in the technical room of the building, being for example in the cellar.

 The main sending device 6 communicates, via a conduit 8, with an auxiliary sending device 9 of an auxiliary bottle 10, so as to control it. Each bottle 7 and 10 has nozzles 11 and 12 for leaving the CO2 which, via conduits 13 and 14, respectively communicate with a pipe 15 opening into the room L.

 As shown in Figure 2, in a neck 16 of the bottle 7 of CO2, is inserted a tube 17 communicating with the main sending device 6.

 The main sending device 6 comprises a valve body 18 delimiting a chamber 19a which communicates with the bottle 7 via an orifice 20 and the tube 17. The pressure of the gas passing through the orifice applies the valve 21 on the sealed face A. The chamber l9a can also communicate with another chamber l9b by means of a cover 24 capable of being perforated by a point 25 fixed to a piston 26. The upper face of this piston 26 is subjected the pressure forces of a fluid coming from a conduit 28.

 The main sending device 6 is connected, on the one hand, by the conduit 8 and by an outlet fitting, to the auxiliary sending device 9 shown in FIG. 1, and, on the other hand, by the conduit 28 and by an inlet connection, to the bottle 7, the inlet and outlet fittings being defined in a ring 27. The element 5 with ET function consists of two solenoid valves 29 and 30 mounted in series on the conduit 28 and electrically excited in parallel by the two blocks 3 and 4 shown in Figure 1, via lines c and d.

 If a fire breaks out, the detector 1 detects smoke and sends, via line a, a detection signal to the first block 3 which processes the information, via its fire detection system, and which sends , via its fire extinguisher system, on the one hand, a signal to an alarm device not shown, and, on the other hand, via line c, a command signal to send C02 A the first solenoid valve 29.

During this time, the detector 2 also detected smoke and sent, via line b, a detection signal to the second block 4 which processes, in the same way as the first block 3, the information and which sends, on the one hand, a signal to another alarm device not shown, and, on the other hand, by line d, a command signal to send C02 to the second solenoid valve 30. The second solenoid valve 30 thus authorizes the passage of the gas transmitted in the conduit 28 to the connector of the main sending device 6, passage made possible by the opening of the valve 29. This gas causes an increase in pressure in the conduits of the ring 27, which triggers a downward movement of the piston 26. The point 25 fixed to the piston 26 perforates the cover 24 and allows the gas contained in the chamber 19a to escape to the atmosphere. The valve 21 is lifted and under the effect of the pressure of the gas contained in the bottle 7 and thus lets it pass towards the outlet nozzle 11. The gas is thus sent, by the conduit 13 and by the pipe 15, in room L. Simultaneously, gas present in the fittings defined in the ring 27 is sent via the outlet fitting of the main sending device 6 in the conduit 8 to the auxiliary sending device 9, shown at FIG. 1, which triggers the opening of the auxiliary bottle 10. The gas contained in the auxiliary bottle 10 is thus sent, via the outlet nozzle 12, the conduit 14 and the pipe 15, into the local L.

 C02 is released in room L after people, alerted, have had time to leave it.

 If one of the two blocks, for example the first block 3, fails and thus transmits to the first solenoid valve 29 an untimely signal to send C02 without having received a corresponding signal from detector 1, the signal coming from the first block 3 does not trigger the sending of CO2 to room L by the main sending device 6, since the second solenoid valve 30 has not received a sending command signal also from the second block 4, and has not therefore not allowed the passage of gas in the conduit 28. This prevents any untimely sending of C02 caused by the failure of one of the two blocks 3 or 4.

 Finally, if lightning causes the emission of an untimely signal to send CO2 to one of the lines c or d, for example line c, the first solenoid valve 29 receives a send command signal and allows gas to pass through line 28. However, line d is at a sufficient distance from line c so as not to be damaged by lightning. No untimely C02 send command signal is created in this line. The second solenoid valve 30 does not authorize the passage of gas in the conduit 28. The disturbance due to lightning does not result in an untimely sending of C02.

Claims (5)

 1. Fire extinguishing installation in a room (L), comprising a source of fluid (7) with extinguishing property which, under the action of a sending device (6), communicates with the room (L ), and two fire detectors (1,2) arranged in the room (L) and connected in parallel to an electronic control circuit of the main sending device (6), characterized in that the electronic control circuit comprises , connected respectively to the two detectors (1,2), two blocks (3,4), and the two blocks (3,4) are connected, by lines (c, d), to the main sending device (6) by means of a so-called AND function element (5) which transmits a signal to the main sending device (6) only when it receives signals from the two blocks (3 and 4) at the same time.  2. Installation according to claim 1, characterized in that the line length between the element (5) with AND function and the main sending device (6) - is less than that between the element (5) with function AND and the two blocks (3, 4).  3. Installation according to claim 1, characterized in that the element (5) with ET function is mounted on the fluid source (7).  4. Installation according to any one of the preceding claims, characterized in that the first line (c) between a first block (3) and the element (5) with AND function and the second line (d) between a second block (4) and the element (5) with AND function are, over most of their length, distant from each other so that a localized external disturbance, in particular lightning, acting on one lines (c), do not act on the other (d).  5. Installation according to any one of claims 1 to 4, characterized in that a conduit (28) puts the source of fluid (7) in communication with an inlet connection (32) of fluid of the sending device main (6) and the element (5) with AND function comprises two solenoid valves (29,30) mounted in series on the conduit (28) and electrically excited in parallel by the two blocks (3,4).