RU2254614C2 - Autonomous fire detection, fire alarm and fire fighting means launching system - Google Patents

Abstract

FIELD: fire fighting technologies.

SUBSTANCE: system functionally includes linear heat sensor, capillary, router, resilient tanks, chamber of water-activated power source, temperature valve for setting activation level, sound alarm with timer, commutator with executive devices and device for controlling circuits of executive devices launch and removal of system elements. Device provides for control of integrity of executive means launch systems, control of tear in circuits of initiators of fire fighting means launch, control of removal of system elements, control of pressurization state of measuring pipe by resilient tank with volume equal to 1-2 sm³; normal element used as power source in standby mode allows to provide for operation of system on standby mode for up to 10-15 years. Also system can be launched manually using resilient tank with volume 5-10 sm³, because system is fully autonomous and fully spark-safe in standby mode.

EFFECT: simplified operation, lower costs, broader functional capabilities.

9 cl, 7 dwg

Description

The invention relates to the field of fire extinguishing, in particular to fire fighting equipment, namely, autonomous systems for detecting fire, fire alarms, launching fire extinguishing means, monitoring the state of the system.

A self-contained non-volatile device is known, see RF patent 2046614 from 04/08/91. International application PCT / RU 92/00071 with priority 08.04.91, consisting of a sensor and a manual starter. However, this known non-volatile device has a number of disadvantages, namely, this sensor is point-wise, therefore, the heat flux can be shielded, which does not allow to objectively reflect the development of fire in the protected room, and finally, the state of the galvanic circuits for starting fire extinguishing means is not provided.

Autonomous devices made in the form of an autonomous heat starter are known, patent RU 2098157 dated 05/17/95 and 2101059 dated 10/06/95. These devices combine a solid fuel extinguisher gas generator with a trigger mechanism that functionally acts as a heat detector. The disadvantage of such devices is the accuracy, the inability to control the state of the system.

Autonomous non-volatile devices consisting of a heat-sensitive extended element are also known, see patent RU 2026277 application 1991, and fire extinguishing means. The operation of this device on the basis of the TSSh is based on the transfer of a heat pulse from the source of ignition, in contact with the TSSh or when the ambient temperature rises, for example, above 190 ° C, to fire extinguishing means. When ignited at any point in the HF, a heat pulse propagates with a high speed of at least 100 mm / s and sequentially launches the required amount of fire extinguishing means. Thus, the TSSh in combination with fire extinguishing means is an autonomous device. The disadvantages of such devices include the change in the temperature-sensitive cord over time of their mechanical characteristics, namely: the elasticity is lost, the TPSh becomes brittle, the unevenness of the burning rate up to attenuation, the inability to work in aggressive environments, the low mechanical resistance to vibration, the inability to control latent mechanical damage Tchsh.

The closest analogue to the claimed invention is a linear thermal fire detection system, - Transafe, see the journal Communication and Telecommunication Security Systems, 1998, p. 37. Transafe consists of a membrane pressure sensor, an electronic processing unit to which a copper measuring tube is connected, and a reference sensing element. The block contains pressure sensors, an information processing device. Using a measuring tube, the Transafe system monitors the spread of heat over a large area. The change in pressure over a certain period of time, the gradient, is evaluated by the processing unit of the electronic device and compared with the data of the reference temperature sensor. In the case of a given rate of temperature rise characteristic of a fire, a linear thermal fire detection system generates an alarm. However, this system has several disadvantages, namely: the measuring tube is made in the form of one extended measuring tube for the entire protected area to be protected, which in some cases may be insufficient, and this system performs only detection functions, without communication with actuators, and finally, the system in question is not autonomous.

The proposed invention solves the problem of creating an autonomous system that includes elements for monitoring the state of the electrical circuits of actuators, while the design allows you to expand the scope using it when protecting objects with aggressive environments, high hazard and critical objects. The proposed autonomous system, in addition, solves the problem of promptly detecting malfunctions and defects that arise during the preparation and commission of sabotage and terrorist acts at protected facilities, increasing reliability, simplifying the design, minimizing operating costs, fully autonomy, and keeping the system in standby mode for a rather long time 10-15 years old.

This technical result is provided in an autonomous system for fire detection, fire alarm and fire extinguishing means due to the fact that the linear thermal sensor is an extended thin-walled metal tube, which is hermetically closed on one side and connected to the entrance to the capillary, which is exited hermetically connected to the input of the splitter, and one output of the splitter is connected to two elastic containers, and the second output of the splitter is connected to the chamber of the water-activated source, for example through a V-shaped tube filled with an aqueous solution of alkali metal salts, for example, an aqueous solution of sodium chloride, and the chamber of the water-activated voltage source through its capillary is connected to the temperature valve to set the response level, and an alarm with a timer is connected to the output electrodes of the water-activated voltage source, which after a predetermined time interval, connects, in start-up mode, to the water-activated voltage source, the switch, and he, in turn, atelno connects the actuators, wherein in the standby mode via the control device checks the integrity of serially connected circuit including the actuators, resistors and control normally-closed contacts of limit switches included in the switch device.

In the case of a large area, the linear heat detector is designed to provide control over the distribution of heat and the detection of fire over a large area, and is connected through a splitter with a V-shaped tube and two elastic containers.

The chamber of a water-activated voltage source consists of 2 sheets of one-sided foil fiberglass laminated on top of each other through a rubber gasket located along the perimeter of rectangular sheets that face each other with foil copper substrates, while a mixture of potassium persulfate is applied to the copper substrate of one of the sheets coal dust or a silver chloride sheet is applied, having reliable galvanic contact with this sheet, and on which a separator, for example, percale, and a plate or from Inca, or magnesium, which on one side is in close contact with the separator and the other side is galvanically connected to the copper substrate of the second sheet of foil fiberglass, and the copper substrate of these sheets are the output contacts of the water-activated voltage source, and is located and fixed on the perimeter of the chamber of the water-activated voltage source her V-shaped tube, half-filled with an aqueous solution of sodium chloride.

The sound alarm is made in the form of a sound generator and a timer that are connected in parallel to the electrical terminals of the water-activated voltage source, and after its activation, it turns on the sound alarm and timer, which, after a specified time, connects the water-activated voltage source to the switch terminals.

The switch consists of limit switches, fire extinguishing actuators, control resistors, which are connected in such a way that the electrical leads of the water-activated voltage source are connected through the timer contacts to the input terminals of the switch, and one of these terminals, which is common to one of the terminals of the control device, connected through the normally-closed contact of the first limit switch and through the initiator circuit of the first actuator to the second terminal of the switch, this is the start circuit ska of the first actuator, and the normally open one contact of the first limit switch is connected to the second input terminal of the switch, and the second normally open contact of the first limit switch through the normally closed contact of the second limit switch and the circuit of the second actuator, and the normally open contact of the first limit switch with the first input terminal of the switch, this constitutes the start-up circuit of the second actuator, the start-up circuit of the third actuator The property consists of a serial circuit, where the first input terminal of the switch is connected to the second normally open contact of the second limit switch, and through the circuit of the third actuator, along the normally closed contact circuit of the third limit switch, through the normally open contact of the second limit switch, and normally -open contact of the first limit switch, connected to the second input terminal, moreover, to control the integrity of the circuit actuators in parallel normally open The first first contact of the first limit switch is connected to one control resistor, and with the help of the second control resistor, a series circuit is formed together with the first, including the normally-closed contact of the first limit switch, the electrical circuit of the first actuator, the first control resistor, the normally-closed contact of the second limit switch , the electrical circuit of the second actuator, the second control resistor, the electrical circuit of the third actuator, normal a closed contact of the third limit switch, and this sequential electrical circuit connected to the terminals of the control device which performs an integrity check circuit actuators.

The temperature valve for setting the system response level is made in the form of a bellows connected through a capillary to the inner chamber of a water-activated voltage source. The bellows has the ability to change its geometric dimensions when the temperature in the protected room and, accordingly, the pressure in the measuring tube changes; moreover, a small diameter hole is made in the end of this bellows, which is externally sealed by one end of the armature of the magnetic system, for example, made on the basis of the РПСС20 switch moving under the influence of an external force, when the volume of the bellows is changed, and the attractive force of the permanent magnet that counteracts this movement is opposite the end of the armature, to the side of the armature that faces the bellows, a sealed elastic gasket is attached, for example thin vacuum rubber, which allows you to tightly overlap the hole in the bellows, and the level of operation and opening of the valve is determined by the pressure in the measuring tube or chamber, at which the hole in The bellows and the chamber of the water-activated voltage source communicate with the external atmosphere through an open hole in the bellows, and a plate is installed on the surface of the bellows from the side of the capillary tube and in which the axis of rotation of the adjusting screw is fixed, wherein the housing of the system is fixed the second plate with a threaded hole, and the triggering level adjustment is carried out adjusting screw and traveling along with it to the armature of the magnetic system. The design of the temperature valve allows you to smoothly change the initial contact force of one end of the anchor to the bellows hole, which corresponds to the set response temperature and valve opening, which corresponds to the response of the system, and opening the hole occurs abruptly.

The V-shaped cylindrical tube is made in such a way that a film, for example, mineral oil, which prevents the evaporation of the aqueous solution of sodium chloride, is applied to the end surfaces of the aqueous solution of sodium chloride inside it.

Silica gel granules are placed inside the chamber of a water-activated voltage source to reduce humidity when the system is in standby mode.

The linear thermal sensor is connected through a splitter with an elastic capacity with a volume equal to 20-30 cm ³ for the system to operate in the "manual start" mode, when pressed and held in this position, the chamber of the water-activated voltage source is filled with solution sodium chloride from a V-shaped tube.

The linear thermal sensor is connected through a splitter with an elastic capacity of 0.5-1 cm ³ to carry out a leakage test of the linear thermal sensor when pressed and held in this position, while the level of the liquid column in the V-shaped tube should not change during retention time.

The integrity monitoring device of a series-connected circuit of actuators in standby mode is made in the form of an electrical circuit that includes a normal element, for example, X480, a resistor, a switching button, a capacitor, an LED, and the negative electrode of a normal element is connected through a resistor to a normally open contact switching buttons, and one capacitor terminal is connected through a normally-closed contact of the switching button and series-connected electrical circuits device, using control resistors and normally closed contacts of the limit switches included in the switching device, with the cathode of the LED, and the positive electrode of the normal element is connected to the second terminal of the capacitor and the anode of the LED.

The device for automatic periodic integrity monitoring of a series-connected circuit of the executive devices of the system in standby mode is made in the form of an electrical circuit and includes a normal element, for example, X480, a controlled circuit, an alarm device, an ionistor, relay, a switch with corresponding contact groups, a button, electrical capacitors, resistors, diodes, transistors connected in such a way that the positive electrode of a normal element is connected through a normally-closed contacts of the second contact group with the ionistor, and the normally open contact of the second contact group is connected to the warning device, and the positive electrode of the normal element, through the normally open contacts of the first contact group, is connected to one terminal of the monitored circuit and, when the contact of the corresponding relay closes, controls the integrity of series-connected electrical circuits of actuators, using control resistors and normally-closed contacts of limit switches, input They are connected to the switching device, and in parallel to the normally open first contact group, the button for the initial start-up of the circuit is connected, the second terminal of the controlled circuit being connected to the anode of the diodes, where the two cathodes of the first and second diodes form a serial circuit connected in such a way that the cathode of the first diode is connected with the emitter-collector junction of the first transistor, then with the winding of the first relay and with the cathode of the second diode, and the cathode of the first diode is connected through the first capacitance with a minus of the normal element nta and, thus, form a charging circuit for the first capacitance, and the cathode of the second diode through a parallel-connected resistor and the second capacitance is connected to the minus of the normal element and form a charging circuit for the second capacitance. The cathodes of the third and fourth diodes are similarly connected.

The device and operation of the autonomous fire detection system, fire alarm and fire extinguishing means is illustrated by the following drawings and electrical circuits:

figure 1 is a functional diagram of an autonomous system;

figure 2 - design of a water-activated voltage source;

figure 3 - electrical diagram of the switch;

4 is an electrical diagram of a control device;

5 is a design of a temperature valve;

6 is a diagram of the voltage at the output contacts of a water-activated voltage source;

7 is a circuit diagram of an automatic periodic monitoring device.

Functional diagram of the proposed system is presented in figure 1. The system contains a linear thermal sensor 1, which is an extended thin-walled metal tube on the one hand hermetically closed, and on the other through a capillary 2 connected to the entrance to the splitter 4, while the splitter is connected to two elastic tanks 3, 13 and a chamber of a water-activated voltage source 5 moreover, this chamber of the water-activated source through the capillary 12 is connected to the temperature valve of setting the response level 6, and to the output terminals of the water-activated voltage source 5, in parallel An audible alarm 7 and a timer 8 are connected, which, after a predetermined time, connects a switch 10 to the water-activated voltage source 5, which is formed from a series-connected contact circuit of limit switches, actuators, control resistors, and using a control device 9, through this electrical circuit in the standby mode mode, monitors the integrity of the circuit actuators.

The device is a water-activated voltage source shown in the drawing of Fig.2. It consists of a chamber 5, which is formed by two sheets of single-sided foil fiberglass 19, these sheets are arranged so that they face each other with foil copper substrates 15, and a rubber strip 12 is placed between the sheets along the perimeter, inside it is applied to one of copper substrates a thin layer of a mixture of potassium persulfate and coal dust 18, or a sheet of silver chloride is placed that has reliable galvanic contact with this sheet, then a separator 17 is applied to the same plate, for example, cal, and then a plate of zinc 16 or magnesium, which is on one side tightly in contact with the separator, and the other side is galvanically connected to the substrate of the second sheet of foil fiberglass, and copper substrates are the output contacts of the water-activated voltage source 13, and a thin layer of potassium persulfate and coal dust or silver chloride, the separator and the zinc plate occupy 2/3 of the internal volume of the chamber inside the chamber of the water-activated voltage source, and in the free volume of the chamber 9 are placed silica gel 20, and the free volume of the chamber through the opening 10, communicates with the V-shaped tube 11, which is 1/2 filled with an aqueous solution of sodium chloride 8, and a protective film 7 is applied to the surface of the solution inside the V-shaped tube, while the capillary tube 14 connects the internal volume of the chamber of the water-activated voltage source to the temperature valve of the actuation level 6, and the other output of the V-shaped tube is connected to the splitter 4, and the splitter is connected to the elastic containers 3, 21, the capillary 2 and the measuring tube 1.

The switch device is shown in Fig 3 and consists of limit switches with contacts K1-1, K1-2, K1-3, actuators Ш1, Ш2, Ш3, control resistors R2, R2, which are connected in such a way that the electrical leads of the water-activated voltage source , through the contacts of the timer are connected by terminals A, B, of the switch, and the terminal A of the switch, which is common to one of the terminals of the control device A (Figure 4), is connected through the normally-closed contact of the first limit switch K1-1 and through the initiator circuit of the first actuator of device Ш1 with terminal В, this is the starting circuit of the first actuator Ш1, and the normally open second contact of the first limit switch K1-2 is connected to the second terminal B, and the second normally open contact of this first limit switch K1-2 is through a normally closed contact the second limit switch K2-1 and the circuit of the second actuator Sh2 and the normally open third contact of the first limit switch K1-3 is connected to terminal A, this makes up the start-up circuit of the second actuator Sh2, the circuit the start-up of the third actuator Ш3 consists of a serial circuit, where terminal A is connected to the second normally open contact of the second limit switch K2-3 and through the circuit of the third actuator Ш3 via the normally closed contact circuit of the third limit switch through the normally open contact of the second limit switch K2-2 and the normally-open contact of the first limit switch K1-2 is connected by terminal B, moreover, to control the integrity of the circuit of actuators, the norm is parallel The flaxen-open first contact of the first limit switch K1-2 is connected to one control resistor R1, and with the help of the second control resistor R2 together with the first control resistor R1 a series electrical circuit is formed, including a normally-closed contact of the first limit switch K1-1, the electric circuit of the first actuator Ш1, first control resistor R1, normally-closed contact of the second limit switch K2-1, electric circuit of the second actuator Ш2, second control resistor R2, the electric circuit of the third actuating device Ш3, the normally-closed contact of the third limit switch KZ-1, and this serial circuit is connected to the terminal control device AC.

Figure 4 shows a device for monitoring the circuits of the actuators of the system in standby mode and is made in the form of a circuit that includes: a normal element E, a ballast resistor R, a control button K, a capacitor C, a LED CD, AC is a controlled circuit included in the device switch, and the negative electrode of the normal element E through the resistor R is connected to the normally open contact of the control button K, and the common contact of the control button is connected to the capacitor C of the capacitor, and the second freely closed contact of the control button I K through a controlled AC circuit, a serial circuit actuators, limit switches, control resistors connected to the cathode of the LED CD.

Figure 5 shows the temperature valve, which is made in the form of a bellows 22 connected through a capillary 28 to the inner chamber of a water-activated voltage source 5 (Figure 2), and in the end part of the bellows 22 there is a hole of small diameter 23, which is elastic on the outside and hermetically closed by one end of the armature 25 of the magnetic system, made, for example, on the basis of the RPS20 switch moving relative to the axis 29, and a sealed elastic gasket 23 is attached to the inner side of the armature arm 25 facing the bellows 22 Example thin vacuum tires, and on the surface of the bellows 23, by the capillary tube 28, is a plate 30 on which is fixed the axis of rotation of the adjusting screw 27, wherein a magnetic system housing mounted the second plate 31 with a threaded hole in which the adjusting screw 27 is mounted.

Figure 6 shows a typical plot of the voltage at the electrical terminals of a water-activated voltage source, with a comprehensive test of the system at a load corresponding to the load of the starting device and equal to 1.9-2.1 Ohms in time obtained during experimental testing of a prototype of the system, where the AF plot on the plot is time from the beginning of the temperature effect on the linear thermal sensor to the start of activation of the water-activated voltage source, equal to 5 seconds, section FB - time from the start of activation of the water-activated voltage annogo voltage source to trigger the starting device and the beginning of the sound of fire alarm sound, equal to 1.5-2 seconds at a voltage of 0.6-0.65 V, VC portion corresponds to the time of active operation of an autonomous system.

Figure 7 shows a circuit diagram of a device for automatically periodically checking the integrity of the start circuits of fire extinguishing systems and includes a normal element, a controlled AC circuit, a warning device, an ionistor I, relay P1, P2 with corresponding contact groups K1-1 and K2, a button K3, electric capacitances C1, C2, C3, C4, resistors R1, R2, R3, R4, diodes D1, D2, D3, D4, transistors T1, T2, connected in such a way that the positive electrode of the normal element is connected through contacts 3, 2 contact group K2 I, and contact 1 of contact group K2 is connected to the warning device, at the same time, the normal element through the normally open contact group K1-1 controls the AC circuit, series-connected circuits of the starting devices, and parallel to the normally open contact group K1-1 is connected start button of the circuit K3, terminal C of the AC controlled circuit area is connected to the anodes of the diodes D1, D2, D3, D4, where the diodes D1, D2 form a series circuit: cathode D1 - emitter-collector junction T1 - key P1 - cathode D2, and cathode D1 conjunction He through C1 with minus NE and form a charging circuit for C1, and cathode D2 through parallel connected R2, C2 is connected with minus NE and form a charging circuit for C2. Similarly connected are the cathodes of the diodes D3, D4.

The principle of the system is that when a fire occurs, the temperature inside the protected room rises and with increasing temperature, the pressure in the measuring tube 1 increases, see Figure 2, which is transmitted through the capillary 2 through the splitter 4 to the V-shaped tube 11, this aqueous solution of sodium chloride moves in the direction of the internal volume of the chamber of the water-activated voltage source 5. When the specified pressure in the chamber of the water-activated voltage source 5, corresponding to perature actuation system opens the opening 23, see Fig. 5, the temperature of the valve, and the internal volume vodoaktivirovannogo voltage supply chamber 5 cm. 2, communicates with the external atmosphere. In this case, due to the pressure differential between the measuring tube 1 and the chamber cavity of the water-activated voltage source 5, the aqueous solution of sodium chloride through the hole 10 will quickly fill, t <1-2 sec, the internal volume of the chamber of the water-activated voltage source 5 and the separator 17, potassium persulfate mixture will be wetted and coal dust, or silver chloride 18 and a plate of zinc 16 or magnesium, while due to the good hygroscopic properties of the separator 17, sodium chloride electrolyte is retained and a reliable the contact across the entire surface of the zinc or magnesium electrodes involved in the reaction and a mixture of potassium persulfate and coal dust, or silver chloride 18, and as a result of a known chemical reaction, during the activation of a water-activated voltage source at the output terminals 13, a voltage of about 1.2-1.5 V, see Fig. 6., since the internal volume of the chamber of the water-activated voltage source in standby mode is sealed, when there is silica gel in this chamber, the water-activated voltage source has enough long shelf life of 10-15 years, with constant readiness for activation. In the manual start mode, it is possible to start the system using the elastic container 21 by pressing this container and holding it in this position, while the pressure inside the linear thermal sensor rises above the threshold for opening the temperature valve, and an aqueous solution of sodium chloride from the V-shaped tube enters the working chamber of a water-activated voltage source, and the process is repeated as described above, since you can use Z of these chambers of water-activated voltage sources, ennyh sequentially, the voltage supplied further to the buzzer 7 (1), the timer 8 (1), the switch 10 (Figure 1) and the actuating device 11 (Figure 1) is Z × 1,2 volts. After working off the audible alarm sounding time set by the timer, the electrical terminals of the water-activated voltage source are connected to the AB terminals (Figure 3) of the switch. The switch allows you to apply voltage from a water-activated voltage source sequentially to Ne the number of fire extinguishing devices and operates as follows, that the voltage on the circuit from terminal A (Figure 3) through the normally closed contacts of the 1st limit switch K 1-1 and through the circuit of the 1st initiator Ш1 enters terminal B and forms a circuit from terminal A through K1-1, Ш1 to terminal B, through which current flows and ignites actuator Ш1, and the first limit switch is thus connected to the first actuator about when an open flame appears from the first actuator, the button of the first limit switch is released and opens its contact K1-1 and simultaneously closes its contacts K1-2 and K1-3 and prepares the circuit from terminal A through K1-2, K2-1, Sh2 , K1-3 to terminal B, through which the starting current of the second actuator circuit Ш2 flows, as a result, actuator Ш2 ignites and releases the button of the 2nd limit switch, it, by analogy with the button of the first limit switch, opens its contact K2-1, closes pays its contacts K2-2 and K2-3 and prepares the circuit from terminal A, for the actuator Sh3, through K2-3, Sh3, K3-1, K2-2, K1-2 to terminal B, etc., at the same time, the control resistor R1, shunting the contacts K1-2, and the control resistor R2 connecting the contacts C and D, have a resistance of several tens of ohms and do not affect the operation of the circuit in the sequential switching mode of the actuators, and in the control mode of the actuator circuits monitoring of circuits of the 1st, 2nd and 3rd actuators in a circuit from terminal A through K1-1, Sh1, R1, K2-1, Sh2, R2, Sh3, K3-1 to the terminal C of the control device, and thus the control circuit breakage of the actuators Sh1, Sh2, Sh3, etc.

A diagram of a device for manual control of actuator circuits is shown in Fig. 4, and in the initial state, button K commutes one terminal of capacitance C through a controlled AC circuit, which enters the switch device, where actuators, terminal contacts of limit switches, and control resistors R1, R2 are connected in series with the cathode of the CD LED, and at the time of monitoring, the button K briefly connects the capacitor C to the normal element through the ballast resistor and the capacitor C quickly charges in time <1, the time is fixed button in this position, and when the button K is released, this charged capacitance C is discharged to the CD LED via the controlled AC circuit, and a light flash of the CD LED appears, which allows judging about the integrity of the actuator circuits.

As the temperature in the protected room rises, the pressure in the measuring tube rises, and accordingly, in the chamber of the water-activated voltage source and the bellows, which changes its volume, and at a given temperature, a hole in the bellows opens, while the chamber of the water-activated voltage source communicates with the external atmosphere, and due to redundancy pressure in the measuring tube, a solution of a water-activated voltage source from a V-shaped tube is rapidly filled with a sodium chloride solution ki, and at a temperature lower than the set one, the temperature valve is closed and set to the set opening temperature. The installation process, the set temperature of the temperature valve, occurs when the original, hermetically sealed hole in the bellows 22, one end of the armature 25 (Figure 5), using a screw 27 moves the magnetic system with this end of the armature and hermetically closed, then in the volume of the bellows a pressure is created corresponding to the set valve opening temperature, and at this set pressure, by turning the screw 27, we move this end of the armature 25 with the magnetic system to the bellows and reach a position in which it violates I stable position of the armature 25 relative to the magnetic system and the bellows 25, and an abrupt movement of the armature 25 to the other stable position opens the valve hole 23, the fixed position of the screw 27 and the anchor is mechanically translated in an initial position corresponding to closure of openings in the bellows.

The automatic periodic control device operates in such a way that at the initial moment K1-1 is open, contact group K2 is in the position connecting contacts 2-3, button K3 is open, AC - form a closed circuit of the Nth number of series-connected actuators devices, contact circuits of limit switches and control resistors, and to start the device, you must press the K3 button, while there is a fast charge of the capacities C1, C2, C3, C4 for the time determined by the post at a given time t = R × C of the corresponding capacities, t <0.01 sec, then a slow discharge of the capacitances C1, C2, C3, C4 occurs over a time t≈3 min, while the potential difference between the points of the circuit F and K and between by points of the circuit L and M to a certain value at which the transistor T1 opens, relay P1 is activated and by its contact K1-1 closes the charging circuit for capacitors C1, C2, C3, C4, then the process is repeated under the condition of a closed AC circuit. Since the discharge time t1 = R2 × C2 is less than the discharge time t2 = R4 × C4, relay P2 does not work. When the controlled AC circuit breaks, there is no charging current for capacitors C1, C2, C3, C4, and the potential difference between points L and M continues to increase to a certain value at which the transistor T2 opens, the remote switch P2 is activated, which switches terminals 1 and 2, and connects the ionistor to the "Break" sound siren. When the device is operating, a normal element is used as a power source. The work of this normal element in the proposed system occurs according to its passport data:

The energy consumed by a normal element, followed by recovery, according to the passport data should be no more than:

E = V × I × t = 0.003 J, where

V = 1.018 V - voltage at the terminals of a normal element;

I = 6 μA - maximum permissible current passing through a normal element for 60 seconds;

24 hours - time to restore a normal element.

The energy spent by a normal element with subsequent recovery in the proposed device is:

E = V × I × t = 6 nJ, where

V = 1.018 V - voltage at the terminals of a normal element;

I = 6 μA maximum permissible current passing through a normal element for 0.01 sec;

Thus, to restore the voltage at the terminals of a normal element, the time required is 6,000 times less, i.e.: = 24 × 60: 6000 = 0.24 min, or about 15 seconds, the proposed device provides a polling period of 150 seconds, which is ten times more.

Claims (9)

1. An autonomous system for detecting fire, signaling a fire, launching fire extinguishing means in the event of a fire, comprising a linear thermal sensor, an audible alarm and actuating devices (IU) of fire extinguishing means, characterized in that it contains a device for monitoring the integrity of the circuits of the IUT of fire extinguishing means, and a linear thermal the sensor is an extended thin-walled metal measuring tube, which is sealed on one side and connected to the capillary on the other, which is connected to the coupler, and the coupler is connected to two elastic containers and through a V-shaped tube filled with an aqueous solution of alkali metal salts, for example, an aqueous solution of sodium chloride, with a chamber of a water-activated voltage source, the inner volume of the chamber of a water-activated voltage source for communication with the atmosphere through the capillary is connected to the temperature valve for setting the response level, and an audible alarm and a time are connected to the output terminals of the water-activated voltage source an interconnector through which, after a predetermined time, a switch is formed to the terminals of the water-activated voltage source, the fire extinguishing means, their limit switches and control resistors are connected, and one of the terminals of the water-activated voltage source (VIN) is connected through the normally closed contact of the first limit switch and through the circuit the first DUT of fire extinguishing means with another VIN terminal to which a normally open contact of the first limit switch is connected, connected through the first normally closed contact of the second limit switch, the circuit of the second DUT of fire extinguishing means and the second normally open contact of the first limit switch with the first of these VIN terminals, which is common with one of the terminals of the continuity control device of the DUT of fire extinguishing means and connected through the normally open contact of the second limit switch, the start circuit third IUT of fire extinguishing means, normally closed contact of the third limit switch, to which another device terminal is connected the continuity monitoring circuit of the fire protection means ИУ, another normally open contact of the second limit switch and the normally open contact of the first limit switch - with another VIN terminal, while one control resistor is connected in parallel with the normally open contact of the first limit switch, and the other control resistor forms a series circuit from the second and third IU extinguishing media. 2. The stand-alone system according to claim 1, characterized in that the integrity control device of the fire fighting equipment control system contains a normal element, a resistor, a switching button, a capacitor, an LED, and the negative electrode of a normal element is connected through a resistor to a normally open contact of the switching button, the common contact of which connected to the capacitor, the normally closed contact of the switching button through the terminals of the said device is connected to the cathode of the LED, and the positive electrode of the normal element is connected n with the second electrode of the capacitor and the anode of the LED. 3. The autonomous system according to claim 1, characterized in that the device for monitoring the integrity of the circuits of the fire fighting equipment includes a normal element, resistors, an open, withdrawal warning device, an ionistor, a relay, a switch with corresponding contact groups, a start button, electric capacitors, diodes, transistors, moreover, the positive electrode of the normal element is connected through the normally closed contacts of the second contact group of the switch with the warning device "open, removal", the positive electrode of the normal electric through the normally open contacts of the first contact group of the switch is connected to one terminal of the said device, and the start button is connected in parallel to the normally open first contact group of the switch, and the second terminal of the said device is connected to the anodes of the diodes, the cathodes of which form a series circuit of the cathode of the first diode — the emitter-collector junction the first transistor is the winding of the first relay is the cathode of the second diode, and, in addition, the cathode of the first diode is connected through the first electric capacitance with a negative electrode of a normal element with the formation of a charging circuit for the first electric capacitance, and the cathode of the second diode through a parallel connected resistor and a second electric capacitance is connected to the negative electrode of a normal element with the formation of a charging circuit for the second electric capacitance, the cathodes of the third and fourth diodes, the third electric capacitance and fourth electric capacitance with a resistor connected in parallel with it, winding of the second relay, emitter-collector junction Horn transistors are connected in a similar way. 4. The stand-alone system according to claim 1, characterized in that the chamber of the water-activated voltage source consists of 2 rectangular sheets of foil fiberglass, superimposed on each other through a rubber gasket located along the perimeter of the rectangular sheets, which are facing each other with foil copper substrates, while a copper substrate of one of the sheets is coated with a mixture of potassium persulfate and coal dust, or a silver chloride sheet is applied, having reliable galvanic contact with this sheet, and on which are applied a separator, such as percale, and a plate of either zinc or magnesium, which is tightly in contact with the separator on one side and galvanically connected to the copper substrate of the second sheet of foil fiberglass on the other side, and the copper substrates of these sheets are the output contacts of the water-activated voltage source, and in part the perimeter of the chamber of the water-activated voltage source is located and fixed on it a V-shaped tube half-filled with an aqueous solution of sodium chloride. 5. The stand-alone system according to claim 1, characterized in that the sound alarm is made in the form of a sound generator. 6. The stand-alone system according to claim 1, characterized in that the temperature valve for setting the response level is made in the form of a bellows connected through a capillary to the internal volume of the chamber of the water-activated voltage source, and a small diameter hole is made in the end part of the bellows, which is elastically closed from the outside one end of the armature of the magnetic system, and the other end of the armature is in contact with the permanent magnet of this magnetic system, and to the side of the armature that faces the bellows, sealed elastic rokladka, e.g. vacuum thin rubber bellows and on the surface side of the capillary tube fitted with a plate on which the adjusting screw is fixed the axis of rotation, wherein in this case the system is fixed the second plate with a threaded hole, wherein the adjusting screw is mounted. 7. An autonomous system according to any one of claims 1 and 4, characterized in that the V-shaped cylindrical tube is filled with a solution of sodium chloride and is made in such a way that a film, for example, mineral, is applied to the surface of an aqueous solution of sodium chloride on both sides of the V-shaped tube oil that prevents the evaporation of an aqueous solution of sodium chloride. 8. The stand-alone system according to any one of claims 1 and 4, characterized in that the chamber of the water-activated voltage source is made in such a way that silica gel granules are placed in the inner chamber, in its upper part, to reduce humidity when the system is in standby mode. 9. The stand-alone system according to claim 1, characterized in that the linear thermal sensor is connected through a splitter with two elastic containers, one with a volume of 20-30 cm ³ and the other with a volume of 0.5-1 cm ³ .

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