SU669373A1 - Fire alarm - Google Patents

Description

t

The invention is intended for use in fire protection systems where high reliability and accuracy of a fire alarm signal is required, in particular, can be used in aviation.

The known fire alarm system contains a sensor that converts some physical factor characteristic of a fire, such as temperature, into an electrical signal, and an electronic threshold device with an electromagnetic relay at output 1. When the sensor signal of a certain predetermined value is exceeded, the threshold device and the electromagnetic relay operate. The pins include a fire indicator, such as a light board.

Closest to the proposed invention, a fire alarm device using redundancy of signal paths or their elements 2.

The fire alarm device contains power supply units, and in each channel a sensor, a threshold unit and two control relays, has fire and fault indicators and two alarm paths, each of which has a separate power supply and contains a sensor and electronic actuator with two control relays output One of the relays, the control relay, Fire, fires when a fire occurs, and the other, the control relay Fault — upon failure, for example, a short circuit to the housing, a sensor, or when there is no voltage on the power bus. The fire indicator turns on only when the control relay fires in both signal paths. When the relay is triggered, “A fault in one of the paths lights up the board. A fault is in the cockpit, and the flight engineer alternates by checking the signal paths, detects the fault path, turns it off, and the system then functions as unreserved.

Claims (3)

However, such a system is not reliable enough, since it is impossible to automatically disable the faulty path.  In addition, the system does not provide the full amount of redundancy, as it does not generate a malfunction signal if the electronic device fails or the Fire control relay and in the event of a malfunction any of these elements will not be able to detect a fire.  The operation of such a system requires an additional source of information — an indicator of non-sensitivity — in the cockpit, which is undesirable under the conditions of the information load of the crew of modern aircraft.  The purpose of the invention is to increase the reliability of the device.  This is achieved by introducing a delay unit, a pulse generator, a switching unit, two limiters, a sensor connected to the first input of the threshold unit to the fire alarm device, the output of which is through the winding of the first control relay and connected in series to the first limiter and winding of the second the control relay is connected to the zero-potential bus, as well as through the winding of the second control relay to the potential-zero bus, the second input of the nopoiOBoro block and the first input of the switching block are connected to the positive terminal of the first power supply unit, the output of the pulse generator is connected to the second input of a non-switching unit, the third input of which is connected to the output of the threshold unit, the input of the pulse generator and the fourth input of the threshold unit are connected to the positive terminal of the second power supply unit, the output of the switching unit is connected to the third through the delay unit the input of the threshold unit and through the second limiter with the winding of the second control relay, the first and second outputs of the device through the contacts of the first and second control relay Ina with a positive terminal of the first power supply.  The threshold block contains resistors, a diode, a pp transistor, a pp transistor, a zener diode, an amplifier swept through the first positive feedback resistor, one of the inputs of the amplifier is connected via a zener diode to the neutral bus, through the second resistor with the first input of the threshold unit, through the third resistor is connected to the second input of the threshold unit, the other input of the amplifier is connected to the first input of the threshold unit and through the fourth resistor to the zero potential bus, the control input of the threshold unit is connected through Consequently, a connected diode and a fifth resistor with a second resistor and through a sixth resistor with a zero potential bus, the output of the amplifier is through the seventh. my resistor is connected to the base of the pnp transistor, the emitter of which is connected to the first input of the amplifier, the collector is connected to the pnp transistor base through the eighth resistor, which is connected to the second input of the threshold unit to the second resistor the emitter, and the collector of the transistor is connected to the output of the threshold unit.  The switching unit contains a ppp transistor, diodes, resistors, zener diodes, two npp transistors, the emitters of which are connected and connected via a zener diode to a zero potential, the bases of pnpp transistors are connected via the first and second resistors respectively with a zero potential bus, the collector of the first pnp transistor is connected via the first diode to the base of the second pnc transistor, the first input of the switching unit is connected via a third resistor to the collector of the first npp transistor The resistor and the second diode with the collector of the second pnp transistor, which is connected through the fifth resistor to the pnp base of the transistor, which is connected to the emitter of the pnp transistor and the first input of the switching unit through the sixth resistor, the input blocking and the third input of the switching unit through the first and second chains of series-connected resistor and diode are connected to a common point, which is connected via the ninth resistor to the anode of the second diode and through the third chain from a series-connected diode and resistor Connected to the second input of the switching unit.  FIG.  I is a diagram of the proposed fire alarm device; Fig 2 - waveforms illustrating the nature of the signals at the nodal points of the alarm device; in fig.  3 and 4, respectively, of the threshold element and the switching element.  The fire alarm device contains the alarm paths 1 and 2 and the fire indicator 3.  The paths include sensors 4 and 5, respectively, for paths 1 and 2, threshold blocks 6 and 7, power supply blocks 8 and 9, which are sources of stabilized voltage, switching blocks 10 and 11, generators 12 and 13 pulses, blocks 14 and 15 delays and control relays 16-19.  Threshold blocks 6 and 7 in each path, in addition to the main inputs to which sensors 4 and 5 are connected, have control inputs and are designed so that when an electric signal arrives at these inputs, they are triggered only if the sensor is healthy.  The switching blocks 10 and 11 in each path have Start inputs connected to the generator 12 and 13 pulses, Reset inputs connected to the outputs of the threshold blocks 6 and 7, and additional inputs, and the switching blocks 10 and 11 are designed so that when the deviation supplying them with voltage from a nominal value to a greater or lesser side, the switching unit is forcibly closed, and when the voltage on the auxiliary input rises above this value, the switching units 10 and 11 are forcibly triggered.  In each path, the outputs of the switching blocks 10 and 11 are connected to the control inputs of the threshold blocks 6 and 7 through the delay blocks 14 and 15, the windings of the control relays 16 and 18 are connected respectively to the outputs of the threshold blocks 6 and 7, and the windings of the control relays 17 and 19 are each to the outputs of the corresponding. their switching blocks 10 and 11 and the threshold blocks 6 and 7 according to the logical scheme OR, in this case through the limiters 20 and 21 in the path 1 and through the limiters 22 and 23 in the path 2.  The power supply of the threshold unit 6 and the auxiliary input of the switching unit 10 in the path 1 are connected to the power supply unit 8 of this path, and the power supply circuits of the non-switching unit 10 and the pulse generator 12 are connected to the power supply unit 9 of the path 2.  Accordingly, the power supply circuit of the threshold unit 7 and the auxiliary input of the switching unit 11 in the path 2 are connected to the power supply unit 9, and the power supply circuits of the switching unit 11 and the pulse generator 13 are connected to the power supply unit 8.  The power supply units 8 and 9 of the paths 1 and 2 have separate power supply 24 and 25 for connecting the system to two independent power supply units 26 and 27.  In the indication circuit of the system, normally open contacts 28, 29 and 30, 31 of two contact groups of control relay 16 are connected in parallel, while normally open contact 30 of one of these groups is connected to power supply 24, normally closed contact 32 of this group is normally - open contacts 33 of relay 17 are connected to power bar 25, and switching contact 31 of the same group is connected in parallel by normally open contacts 34 and 35 of relay 18 and 19 are connected to one of the terminals of fire indicator 3, the other with its terminal connected to st zero potential.  The input stage of the threshold unit 6 is the amplifier 36, covered by positive feedback through the resistor 37.  The output voltage of amplifier 36 is small if the potential of its non-inverting input, indicated by a “+” sign, is lower than the potential of the inverting input, indicated by the sign “-.  The output voltage of amplifier 36 abruptly increases when the potential of the non-inverting input becomes higher than the potential of the inverting input.  The inverting input of amplifier 36 is connected to a bias source formed by a zener diode 38 connected to the power supply bar of the threshold unit 6 via a resistor 39.  Non-inverting B. xo; i the amplifier is connected to one of the poles of the sensor 4 and through a resistor 40 to the P1INE of zero potential.  The second pole of sensor 4 is connected to the midpoint of a voltage divider formed by resistors 41 and 42 and connected in parallel to the zener diode 38.  The sensor 4 is connected to the input of the amplifier 36 so that the signal from it is connected to the opposite voltage, which is allocated to the resistor 41.  The control input of the threshold unit 6 is connected to the midpoint of the voltage divider through a series-connected diode 43 and a resistor 44.  To the output of the amplifier 36 is connected to the output stages of the threshold unit 6 transistors 45 and 46.  The switching unit 10 is a DC amplifier, the first two stages of which are covered by positive feedback through a resistor 47 and are made on transistors 48 and 49 of the same polarity, but connected to a common emitter circuit.  The base of transistor 49 through diode 50 is connected to the collector of transistor 48, the combined emitters through Zener diode 51 are connected to a common point of the system and are at a potential equal to the national stabilization of this Zener diode.  The inputs “Start and Reset Trigger are connected to the base in. the transistor 48 through the resistors 52 and 53 and the diodes 54 and 55.  An additional input of the switching unit 6 through the resistor 56, the Zener diode 57 and the diode 58 is connected to the base of the transistor 49.  The output stage of the switching unit 10 is a transistor 59, the base of which is connected to the collector of the transistor 49.  The fire alarm device operates as follows.  With the health of all elements of the system and the occurrence of fire in the area where the sensors 4 and 5 are located, each of the sensors 4 and 5 generates an electrical signal that arrives at the main input of the threshold units 6 and 7.  When the signal of sensors 4 and 5 reaches a predetermined value, threshold units 6 and 7 and control relays 16-19 connected to their outputs are triggered.  In this case, the fire indicator 3 is turned on, receiving from the power supply unit 26 via the busbar 24 and the closing contacts 28, 29 and 30, 31 of the control relay 16 and the contacts 32 and 33 of the control relay 18 and 19.  The absence of false alarms in the event of failure of any element of the device is ensured by the fact that in order to turn on the fire indicator 3, at least one control relay in each signaling path is required.  If any one path is falsely triggered, the indication circuit remains open and the fire indicator 3 does not turn on.  For example, if sensor 4 gives a false signal in path 1 and threshold block 6 and control relay 16 and 17 are triggered, the voltage from power supply block 26 through closed contacts 28, 29 and 30, 31 will go to normally open contacts 34, 35, the remaining serviceable tract 2, and the inclusion of indicator 3 will not occur.  The device will remain operational, since in the event of a fire, path 2 is triggered and contacts 34 and 35 close the fire indicator circuit 3.  The ability to detect a fire in case of failure of any element of the device is achieved by the fact that the means of automatic control makes a continuous automatic check of the health of the sieteme paths and, if a path fails to function, disable it.  The health check of paths, for example, path 1, is performed as follows.  Pulse generator 12 periodically sends pulses (oscillogram u1, FIG. 2) to the input "Start switching unit 10.  Triggering the switching unit “10” sends a signal Ui to the input of the delay unit 14, made, for example, on RC elements.  The voltage Us at the input of the delay unit 14, increasing exponentially, arrives at the control input of the threshold unit 6.  At the moment when the voltage U reaches the operation voltage Ucp of the threshold unit 6, the latter is triggered with the Ter delay and the output signal U4, received at the input "Resetting the switching unit 10, resets it.  Steady resetting of the switching unit 10 is ensured by the fact that the duration of the triggering pulse TU is chosen by the head. a smaller value, and the signal to the input "Reset of the switching unit 10 comes after the disappearance of the signal at the input" Start.  When the switching unit 10 is triggered, the signal at the input of the delay unit 14 becomes zero, and at the output it decreases exponentially and, decreasing to the release voltage UOT of the threshold unit 6, turns it on with a delay of time T.  The path map returns to its original state, thereby completing the control cycle.  During each control cycle, the control relay coil 16 at the output of the threshold unit 6 is under voltage for the time ToT.  and the control winding 17, connected to the outputs of the threshold unit 6 and the switching unit 10 according to the OR circuit, is under voltage during the control cycle of TCr Ter + TOT.  The time constant of the delay unit 14 defining the intervals Ttp and Tflf is chosen so that the control cycle time Tii is known to be shorter than the response time of control relay 16 and 17, and, d the repetition TB of triggering pulses is known to be greater than the response time of the relay; therefore, control relays 16 and 17 do not operate during control cycles and cannot cause false triggering of path 1.  In case of sensor 4 or threshold block 6 malfunction, as well as voltage drop of power supply unit 8 or interruption of power supply via bus 24, for example, when power supply unit 26 is out of operation, threshold unit 6 will not operate when switching unit 10 is triggered and will not reset him.  In this case, the control relay 17 at the output of the switching unit 10 operates and with its contacts 33 supplies power from the power supply unit 27 through the normally closed contacts 31 and 32 of the control relay 16 to the contacts 34 and 35 of the relay 16 and 18 of the path 2.  Now, in the event of a fire, path 2, remaining healthy, will work and contacts 34 and 35 will turn on the fire indicator 3.  In case of an emergency increase in the output voltage of the power supply unit 8, which can disrupt the operability of the threshold unit 6 and the path 1 as a whole, the switching unit 10 is triggered by the increase in voltage at the auxiliary input connected to the power supply unit 8.  The switching unit 11 in the path 2, which is powered by the power supply unit 8, does not operate in this case, since it is designed so that it locks up when the supply voltage deviates from the nominal voltage both in the smaller and in the larger direction.  For the same reason, the switching unit 11 will not work even with an emergency lowering of the output voltage of the power supply unit 8.  This makes impossible the false triggering of the system both when raising and lowering the output voltage of the power supply unit 8.  At the same time, the system as a whole remains operable, since in the event of a fire, the remaining healthy path 2 will operate and turn on the fire indicator 3.  Automatic monitoring of the operability of the path 2 is performed similarly to the monitoring of the path 1.  If the sensor 5, the threshold unit 7, the power supply unit 9 fails or when the power supply is terminated, the switch unit 11 and the control relay 19 are activated on the busbar 25.  Now, in the event of a fire, the remaining intact signal path 1 will also work with its contacts 28, 29 and 30, 31 through the closed contacts 35 of relay 19 and the fire indicator 3 will turn on.  The system operability test circuits do not turn on relay 16 and 18 of control paths I and 2, and preservation of system operability when any of these control relays fails is ensured by parallel connection of control relay 16 and 17 windings and relay 18 and 19, as well as parallel connection of contacts 28, 29 and 30, 31 relay 16 controls.  When duplicating, the fire alarm system maintains its operability even if any element of the control means fails.  For example, the failure of the generator 12, the delay unit 14, the failure of the switching unit 10 or the failure of the control relay 17 does not disrupt the operation of the path 1 and only means that the control operations of the path 1 have ceased.  The spontaneous triggering of the switch, its unit 10 and the control relay 17 means the false triggering of only the signal path 1 and, therefore, cannot cause either a false trigger or a loss of the fire detection ability of the device as a whole.  The device maintains its operability even if any of the limiters 20-23 fails.  For example, in path 1, an open circuit of the limiter 20 will violate the backup circuit of relay 16.  The breakdown of limiter 20 will lead to the self-activation of the switching unit 10, which, just as in the case of the breaker of limiter 21, is equivalent to the termination of control operations of the path 1.  In all the cases listed, path 1 and the device as a whole retain the ability to detect fire.  The breakdown of the limiter 21 will lead to the formation of a positive feedback circuit of the threshold unit 6 through the delay block 14 and the control input, which will cause the spontaneous triggering of the threshold block 6 and path 1.  However, this cannot cause a loss of performance of the device as a whole.  Special requirements are imposed on such device elements as threshold units 6 and 7 and switching elements 10 and 11.  The threshold unit of the system must have a control input and operate either when a sensor signal is received when a fire occurs, or when a signal is sent to the control input, provided that the sensor is fixed and the threshold unit of the system must have the Start input, the Reset input and the auxiliary input and locked irrespective of the presence or absence of a signal at the “Start” input, when the supply voltage deviates from the nominal value, and also unlocked regardless of the presence or absence of a signal at the “Reset” input, when the signal is increased ala (voltage) on the additional input is higher than the nominal value.  Schemes of the threshold block and the switching block that meet the specified requirements are given in FIG.  3 and 4.  As the sensor 4 of the fire alarm system used thermocouple.  In the absence of a fire, the signal from sensor 4 is close to zero.  The signal through the sensor circuit 4 is fed to the input of the amplifier 36.  The output voltage of amplifier 36 is small and, since the base of transistor 45 is connected to the output of amplifier 36, and the emitter of transistor 45 is under the potential of Zener diode 38, transistors 45 and 46 are locked, and the voltage at the output of threshold unit 6 is zero.  In the event of a fire or an emergency temperature rise at the location of sensor 4, the signal from it increases even at the moment when it exceeds the voltage, the separation yush. If it is on resistor 41, amplifier 36 switches, the voltage at its output jumps up, the output transistors 45 and 46 of the threshold unit 6 are unlocked, and a high potential appears at its output.  In the absence of a fire, the threshold unit 6 can be triggered when a positive potential is applied to the control input, provided that sensor 4 is in good condition - there is no open circuit and a short circuit.  In this case, the potential of the control input of the threshold unit 6 through the diode 43 and the resistor 44 is supplied to the midpoint of the voltage divider formed by the resistors 41, 42 and through the sensor circuit 4 to the inverting input of the amplifier 36, which triggers the trigger unit 6.  When sensor 4 is broken, the positive potential cannot reach the non-inverting input of amplifier 36.  This input through the resistor 40 receives the zero potential of the common point of the system, while the inverting input is at a positive potential, reduced from the Zener diode 38.  The threshold unit 6 is not triggered.  When sensor 4 is closed on the case, which is a common point of the system, short or through sufficiently low resistance, the potential of the case through the resistance of the circuit and the thermocouple circuit falls on the non-inverting input of amplifier 36 and, just as in the previous case, prevents the threshold unit 6 from triggering if there is a positive potential at its control input.  Thus, the operation of the threshold unit 6 when a signal is applied to its control input indicates the health of both the sensor 4 and the threshold unit 6 itself.  The triggering of the switching unit 10 is effected by a negative polarity pulse fed to the trigger input.  When this happens, transistor 48 is locked, transistor 49 is unlocked, current through resistor 47 decreases, and transistor 4-8 after removing the trigger pulse remains locked by the potential of the common point of the system, post uioioiu-iM to the base of transistor through resistor 60.  When the transistor 49 is unlocked, the transistor 59 opens at the same time as B1) 1. The trigger trigger io is a positive notcial.  The reset of the switching unit is made by a positive potential, which is fed to the input "Reset.  Here, the transistor 48 is unlocked, and the transistors 49 and 59 are locked.  Potenti; at the output, the switch of the block drops to zero.  After the disappearance of the input voltage, the Reset, the switching unit is kept locked. A state of feedback current through the resistor 47.  By reducing the supply voltage below a certain value, approximately corresponding to the stabilization of the Zener diode 51, trans. The reading unit 10 will be locked even if there is a signal at the Run input, since the collector voltage of transistor 49 will drop to zero.  When the supply voltage rises above a certain value, the feedback current through the resistor 47 returns so much that the start pulse will not be able to close the transistor 48 and the switching unit 10 remains in the locked state even if there is a signal at the Start input.  The stabilization voltage of the Zener diode 57 in the auxiliary input circuit is selected such that, at the nominal voltage level at this input, the Zener diode 57 is in the conducting state and affects the operation of the switching unit.  When the voltage is additionally increased. At an input higher than a certain value, the Zener diode 57 goes into a conducting state, a current passes through the auxiliary input, which opens the transistors 49 and 59, and the switching unit 10 is activated even if the positive potential is present at the input "Reset."  The switching unit 10 is thus locked, regardless of the presence of a signal at the Start input, when the supply voltage deviates from the nominal value and forcibly triggers when the voltage on the auxiliary input is higher than this value, which meets the requirements set by the duplicated system this item.  To prevent the switching blocks 10 and 11 from working together in both paths in the circuit of each switching block 10 and I, there is a blocking input connected to the base of transistor 48 through a resistor 61 and a diode 62.  The blocking input of the switching unit 10 or 11 of each path is connected to the output of the switching block of the other path.  In the case of the operation of one of them at the input of the blocking of the other, but a positive voltage opens, which opens the transistor 48, and the switching unit 10 or 11 locks itself, which makes it impossible for them to operate together. When a fire alarm system is duplicated, the probability of a false alarm of the system is 500-2,000 times lower than the probability of a false alarm of a non-redundant fire alarm system.  Approximately to the same extent, the likelihood of the system not functioning decreases.  Since in aviation all the false alarms or non-functioning of the fire alarm system are associated with flight delays or forced landing of an aircraft, the use of redundancy in the fire alarm system improves the reliability of the system and the safety of air traffic.  Claim I.  A fire alarm device containing power units, and in each channel a sensor, a threshold unit and two control relays, characterized in that, in order to increase the reliability of the device, a delay unit, a generator, and a channel are inserted into each channel. pulses, switching unit, two limiters, the sensor is connected to the first input. m threshold unit whose output through the winding of the first control relay and serially connected first limiter and the winding of the second control relay is connected to the zero potential bus, and also through the winding of the second control relay to the zero potential bus, the second input of the threshold unit and the first input of the switching unit with the positive terminal of the first power supply unit, the output of the pulse generator is connected to the second input of the switching unit, the third input of which is connected to the output of the threshold unit, the input The pulse generator and the fourth input of the threshold unit are connected to the positive terminal of the second power supply unit, the output of the switching unit is connected to the third input of the threshold unit via the delay unit and through the second limiter to the winding of the second control relay, the first and second outputs of the device are connected with the positive terminal of the first power supply.  2  The device according to claim.  1, characterized in that the threshold unit contains resistors, a diode, a pnp transistor, a ppp transistor, a zener diode, an amplifier swept through the first positive feedback resistor, one of the inputs of the amplifier is connected via a zener diode to a zero bus potential, through the second resistor with the first input of the threshold unit, through the third resistor connected to the second input of the threshold unit; another input of the amplifier is connected to the first input of the threshold unit and through the fourth resistor to the zero potential bus; the control input of the threshold unit is connected through a serially connected diode and fifth fifth resistor to the second resistor and through the sixth resistor to the zero potential bus, the output of the amplifier through the seventh resistor is connected to the base of the pnp transistor, the emitter of which is connected to the first input of the amplifier, the collector is connected via the eighth resistor to the base of the pnp transistor, which and by a ninth resistor is connected to the second input of the threshold unit connected to the emitter and the collector p-n-p transistor coupled to the output of the threshold unit. 3. The device according to claim 1, characterized in that the switching unit contains a pp transistor diodes, resistors, zener diodes, two np p transistors, the emitters of which are combined and connected via a zener diode to a potential-potential bus, base p -r-p transistors through the first and second resistors are connected respectively to the zero potential bus, the collector is the first start . / I Add / Thread1, Now Sxoff one Additional bhoz juffycf S GO npp transistor through the first diode is connected to the base of the second npp transistor, the first input of the switching unit via the third resistor is connected to the collector of the first npp transistor, connected in series through the fourth resistor and the second diode to the collector of the second pnp transistor, which through the fifth resistor is connected to the pnp transistor base, which through the sixth resistor is connected to the emitter of pnp transistor and the first input of the switching unit, the blocking input and the third input of the switching unit through the first and second c Chains from series-connected resistors and a diode are connected to a common point, which through the ninth resistor is connected to the anode of the second diode and through the third chain of series-connected diode and resistor to the second input of the switching unit. Sources of information taken into account in the examination 1. USSR author's certificate number 570077, cl. G 08 B 17/06, 1975. 2. David R. A. Concorde power plont fire protection system “Aircraft engineering 1971, No. 43, No. 5. and. G „ } ll J X far . Th ".2 itiJ vkadAdditional SnoKupoSmSxod Nutrition  Output D / 7.4