RU2047907C1 - Device for automatic redundancy of warning lamps - Google Patents

Abstract

FIELD: light warning. SUBSTANCE: invention relates to redundancy of warning lamps positioned in places difficult to reach and critically important. Device has signalization cells containing nonredundant and redundant warning lamps, two-position ring thyristor pulse counters and electronic transistor keys. By pressing test button positive supply pulses go through bus from power supply source and provide for no-contact switching off of redundant and switching on of nonredundant lamps immediately in all signalization cells. If nonredundant warning lamp burns out in any signalization cell proper electronic transistor key ensuring supervision over presence of supply voltage across nonredundant lamp switches on thyristor of second position of corresponding ring thyristor pulse counter and consequently cuts in necessary redundant warning lamp. EFFECT: enhanced operational reliability and safety. 1 dwg

Description

 The invention relates to light signaling, in particular to devices providing automatic redundancy of signal lamps.

 A device is known for automatic reservation of signal lamps, containing electronic relays assembled on transistors, the control signals for which are removed from the secondary windings of the transformers. The primary windings of these transformers are connected in series with the main lamps. The relay is powered from a separate source containing a transformer, a diode bridge, a capacitor. When the main lamps are working, the transistors are open and the relays are on. The relay contacts in the power supply circuit of the backup lamps are open and the lamps are off. When the main lamp burns out on the primary winding of the corresponding transformer, and consequently, on the basis of the transistor, the voltage disappears, the transistor closes, the relay turns off and its closed contact provides power to the backup lamp. After replacing the blown main lamp, the device automatically returns to its original state (1).

 The disadvantages of this known device for automatic backup of signal lamps include: power consumption in standby mode, the use of transformers as control elements with transistor keys, through the primary windings of which the full currents of the main signal lamps flow, the use of electromagnetic relays, the contacts of which provide power to backup lamps. All this greatly complicates the design of the device and reduces its reliability.

 The closest in technical essence to the claimed device is a device selected for prototype for automatic reservation of signal lamps, in which the main lamp is connected in series with the current relay winding.

 The contacts of the current relays are included in the control electrode circuits of powerful triacs connected in series with backup alarm lamps. When the main alarm lamp burns out, the current relay is turned off and its closed contact provides voltage to the control electrode of the triac, turning on, the triac provides the supply voltage to the backup alarm lamp (2).

 The disadvantage of this simple in design device is the presence of an electromagnetic current relay, connected in series with the main alarm lamp. The current relay in standby mode consumes significant power, since the full current of the main alarm lamp flows through its winding, the current relay is significantly in size, and the reliability and uptime are much lower than that of the contactless element of the triac circuit. In addition, in this device it is impossible to check in advance at any time the serviceability of the backup alarm lamp, and such a need arises especially in difficult working conditions, when before turning on the main alarm lamps it is necessary to make sure that all backup alarm lamps are also working.

 The aim of the invention is to expand the functionality and increase the reliability of the device.

 The goal is achieved in that the device contains two-digit ring thyristor pulse counters according to the number of alarm lamps, the output of the first discharge of each counter connected to the output of the first main alarm lamp, and the output of the second discharge connected to the second backup alarm lamp. The control inputs of all thyristor ring impulse counters are connected through the make contact of the test button to the pulse voltage bus of the power source, and through the make contact to the negative bus of the power source. The control input of the electronic key, made in the form of a voltage divider consisting of series-connected resistors, one of which is connected in parallel with a timing capacitor, is connected in parallel with the main alarm lamp, and an additional alarm lamp is connected to the pulse voltage bus of the power source.

 Comparative analysis with the prototype shows that the inventive device is characterized in that the main and backup alarm lamps are connected to the load outputs of the first and second digits of the double-row pulse counter, respectively. The control inputs of each of the thyristor counters are connected to the pulse voltage bus of the power source through the make contact of the common signal lamp test button, which allows for serviceable main alarm lamps to remotely check the health of all backup alarm lamps, while switching the load circuits is a non-contact way due to the switching of the thyristors .

 Thus, the claimed device for automatic reservation of signal lamps meets the criteria of the invention: novelty.

 Comparison of the claimed solution not only with the prototype, but also with other technical solutions in this field, namely with devices for automatically backing up signal lamps, shows the absence of electronic keys in them that provide voltage control on the main lamps and the automatic inclusion of a backup alarm lamp during burnout main lamp. In this case, the inclusion of a backup alarm lamp is provided through the thyristor of the second discharge of the ring pulse counter, i.e. in a non-contact way. In addition, the presence of an additional alarm lamp connected to the busbar of the pulse voltage of the power source, eliminates the influence of possible contact bounce of the button for checking the health of additional alarm lamps. All this allows us to conclude that the proposed technical solution meets the criterion of "significant differences".

 The drawing shows an electrical schematic diagram of a device for automatic backup signal lamps.

 The device for automatic backup of signal lamps contains a power source 1 with a bus 2 pulse voltage, n-cells 3 alarm, each of which contains the main signal lamp 4 and a backup signal lamp 5, two-digit thyristor ring pulse counter 6, an electronic switch 7, an additional signal lamp 8 connected to the bus 2 of the pulse voltage of the power source. Each thyristor two-bit annular pulse counter 6 contains thyristors 6.1 and 6.2 with the corresponding elements that make up two counting cells. Thyristor 6.3 performs an auxiliary role and is designed to lock thyristor 6.2. The anodes of the diodes 6.4, 6.5 are interconnected and the point of their connection is the control input of the ring counter 6. All control inputs of the ring pulse counters are connected to the negative bus of the power source 1 through the opening contact of the test button 9, and through the closing contact of the button 9 to the pulse voltage bus 2 power source. In addition, the ring pulse counter contains switching diodes 6.6, 6.7, switching capacitors 6.8, 6.9; control resistors 6.10, 6.11.

 The control resistors 6.10 and 6.11 are included in the control electrode circuit of thyristor 6.1 and provide automatic installation of the initial state of the counter after applying voltage to the power supply 1. The anodes of thyristors 6.1, 6.2 are the outputs of the discharges of the pulse counters and are connected to the corresponding main 4 and backup 5 alarm lamps. The anode of thyristor 6.3 is connected to the corresponding load resistor 6.12. Between the cathode and the control electrode of the thyristors 6.2 and 6.3, the corresponding galvanic coupling resistors 6.13 and 6.14 are connected.

 Each electronic transistor switch 7 is made according to a serial signal inversion circuit and contains a resistor voltage divider, consisting of series-connected resistors 7.1 and 7.2, providing control of the supply voltage on the main signal lamp 4. A time delay capacitor 7.3 is connected in parallel with the resistor 7.1. The electronic key contains transistors 7.4 and 7.5; the base of the first transistor through a bias resistor 7.6 and the collector of the second transistor through a load resistor 7.7 are connected to the control electrode of the thyristor 6.2 ring thyristor pulse counter 6. The base of the second transistor 7.5 is connected to the collector of the first transistor and through its collector load resistor 7.8 with a negative busbar of the power source. Through the resistor 7.9, a positive connection is made between transistor 7.5 and the input of transistor 7.4 and at the same time negative current feedback arises in a cascade on transistor 7.4.

 A device for automatic backup signal lamps works as follows. When applying voltage to the device via bus 2, positive voltage pulses from the power source 1 of a certain amplitude, frequency and duration are sufficient for reliable switching and operation of all elements of the device circuit, both during positive voltage pulses and during pauses between them .

 The initial states of the thyristor ring two-digit pulse counters 6 are set automatically: after the supply of the power supply voltage through the control resistors 6.10, 6.11 and the control circuit of the thyristors 6.1, the currents that unlock these devices begin to flow, and the corresponding main alarm lamps 4 turn on, the remaining thyristors 6.2, 6.3 ring pulse counters 6 in the initial state are locked. Simultaneously with supplying the supply voltage through the circuit, the positive bus of the power source, capacitor 7.3, resistor 7.6 and resistor 6.13 flows through the charge current of capacitor 7.3; an offset sufficient to turn it on is created on the basis of transistor 7.4. Through the resistor 7.9, a positive connection is made between transistor 7.5 and the input of transistor 7.4 and at the same time negative current feedback arises in a cascade on transistor 7.4. Turning on transistor 7.4 puts the second transistor 7.5 into a stable off state. If the thyristor 6.1 turns on during the charge of the capacitor 7.3, which is possible with a working lamp 4, then the necessary bias voltage to maintain the transistor 7.4 in the on state is removed from the divider on resistors 7.2, 7.1. If during the charge of the capacitor 7.3 the lamp 4 did not turn on, then the bias voltage formed by the resistors 6.13, 7,6, 7.1 based on the transistor 7.4 is not enough to turn it on. The state corresponding to the turned on transistor 7.4 and the locked transistor 7.5, in this case, is a stable state of the circuit, stored only for the duration of the input pulse, determined by the charge time of the capacitor 7.3. When the voltage of the input pulse drops to zero, the circuit goes into a second stable state, namely: transistor 7.4 is turned off, and transistor 7.5 is turned on. As you turn on the transistor 7.5, i.e. in the process of overturning, positive feedback prevails, since the increment of the emitter current in transistor 7.5 is much larger than in transistor 7.4. Turning on, the second transistor 7.5 provides a voltage level at the control electrode of the thyristor 6.2, sufficient to turn it on, and therefore the backup alarm lamp 5. The capacitance of the capacitor 7.3 is chosen such that with serviceable circuit elements, namely thyristor 6.1 and the main alarm lamp 4, their reliable inclusion was first ensured.

 When thyristors 6.1 ring thyristor counters are turned on, the corresponding diodes 6.6 bypass the circuits of these devices and the currents of the control electrodes are sharply reduced. In addition, when thyristors 6.1 are turned on, the reverse voltages on the diodes 6.5 are equal to the voltage of the power source. So, we have the following initial state of the circuit: all thyristors 6.1 of ring double-digit pulse counters are turned on, and therefore all main signaling lamps 4, alarm cells 3, all other thyristors 6.2 and 6.3, as well as second transistors 7: 5 of electronic keys are turned off.

 Suppose that it is necessary to check the serviceability of the backup alarm lamps, in most cases this is a mandatory operation, since after turning on the alarm in standby mode, it will have to work for long periods in hard-to-reach places in difficult weather conditions and you need to be sure that the backup alarm lamp is also working. By pressing the test button 9, the bus 2 of the pulse voltage of the power supply 1 is connected to the control inputs of all thyristor ring pulse counters 6 of the alarm cells 3 and can only go through diodes 6.4 and unlock thyristors 6.2, which, using the appropriate switching capacitors 6.8, lock thyristors 6.1 and all The main alarm lamps turn off.

 After the thyristors 6.2 are turned on, the supply voltage is supplied to all the backup alarm lamps 5, while the control electrode circuits of the thyristors 6.1 are still shunted, but now they are diodes 6.6, and therefore, the thyristors 6.1 cannot be unlocked currents flowing through the resistors 6.10, 6.11. The reverse voltages on the diodes 6.5 are reduced to the residual voltages of the thyristors 6.2, and on the corresponding diodes 6.4 it will be equal to the voltage of the power source. By releasing the test button 9 at the time when the alarm lamp 8 is off, visually make sure that all backup alarm lamps 5 are working. Subsequent pressing of button 9 upon receipt of the next positive pulse of the supply voltage via bus 2 discharges the pulse counters in the same way as described above. However, in the anode circuits of thyristors 6.3 there are no diodes shunting resistors 6.10 and 6.11; therefore, when they are unlocked, not only thyristors 6.2 are locked, but the thyristors of the first discharges 6.1 of the ring pulse counters are again turned on. Resistances 6.12 in the anode circuit of thyristors 6.3 are selected so that the currents in their circuits from the voltage of the power source are less than the holding currents of thyristors 6.3, therefore, after the discharge of the switching capacitors 6.9, thyristors 6.3 are also locked. The pulse counters 6 return to their original state and the main alarm lamps 4 turn on. The test mode is completed and the test button 9 at the point in time when bus 2 no longer has a positive pulse from power source 1, i.e. when the optional alarm lamp 8 is turned off, it must be released.

 Suppose that during the operation of the alarm system, one of the main alarm lamps burns out, one of the main alarm lamps 3.1 burns out, burns out. The current through the circuit of the voltage divider from the series-connected resistors 7.1 and 7.2 of the electronic switch 7 is less than the holding current of the thyristor 6.1 and the latter is turned off. The bias voltage, which is already created by the resistors 6.13, 7.6, 7.1 based on the transistor 7.4, is not enough to maintain it in the on state. The transistor 7.4 turns off, the transistor 7.5 turns on, providing the inclusion of thyristor 6.2 and the supply voltage to the backup signal lamp 5. This ensures automatic backup signal lamps.

 Using the proposed device can significantly expand the functionality of the device, since by simply pressing one button you can check the health of all backup alarm lamps at once, and indirectly, the health of the elements of the alarm cells. The reliability of the design of the device is also increased, since switching, switching on alarm lamps and monitoring the health of the main alarm lamp is carried out only with the help of contactless electronic elements of thyristors and transistors, these elements are characterized by high reliability, low weight and dimensions.

 The use of the proposed device is most effective when the alarm lamps are located in hard-to-reach places that require guaranteed operability of the device as a whole.

Claims (1)

 DEVICE FOR AUTOMATIC RESERVATION OF SIGNAL LAMPS, containing a power supply with a pulse voltage bus, a test button, alarm cells, each of which includes a primary and backup alarm lamp, an electronic transistor switch made according to the serial signal inversion circuit connected in parallel with the main alarm lamp, characterized in that an additional alarm lamp is introduced, and each alarm cell is equipped with a two-digit ring pulse counter, including thyristors by the number of bits of the counter and auxiliary, moreover, the control inputs of the first and second bits of each counter are connected to one of the terminals of the test button connected to the negative bus of the power source, the other terminal of which is connected to the pulse voltage bus of the power source, the outputs of the first and second bits of the counter connected to one of the terminals of the main and backup alarm lamps, respectively, the control output of the transistor switch is connected to the control electrode of the thyristor of the second category, respectively the existing ring counter of pulses, with an additional alarm lamp connected between the negative bus and the bus of the source voltage pulse, the second terminals of the main and backup alarm lamps are connected to the positive bus of the power supply connected to the control electrode and anode circuits of the first and auxiliary thyristors, respectively.

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