RU101241U1 - FIRE ALARM CONTROL UNIT - Google Patents

Abstract

 1. The fire alarm control unit has a microcontroller, an information input / output node, an output key node, a power supply unit, a multiplexer, controlled current limiting nodes for each zone, terminals for connecting protected zones, terminals for connecting sirens, an information input / output node connected to the microcontroller using the first group of inputs and outputs, the second group of outputs of the microcontroller is connected to the inputs of the output key node, the outputs of which are connected to the corresponding terminals for connecting sirens, first The microcontroller’s power output terminal is connected to the first output of the power supply unit, the second output of which is connected to the power output of the output key assembly and the multiplexer, the analog output of which is connected to the analog input of the microcontroller, the third group of outputs of which is connected to the corresponding control inputs of the controlled current limiting units in each zone , the outputs of the controlled nodes of the current limitation in accordance with the zones are connected to the first group of terminals for connecting protected zones, the fourth group exits the microcontroller’s door is connected to the control inputs of the multiplexer, the analog inputs of which are connected respectively to the first terminals of the measuring resistors, and the first power leads of the controlled current limiting nodes are connected to each other and connected to the third output of the power supply, the common bus of which is connected to the second power leads of the microcontroller, the output node keys, multiplexer, controlled current limiting nodes and with second terminals of measuring resistors, characterized in that we control

Description

The utility model relates to the field of fire alarm and can be used in fire alarm systems to analyze the status of fire detectors, process and provide information in an acceptable form for the operator, as well as to automatically transmit signals to sirens and central monitoring panels.

The well-known receiving and control device [Radiohobby magazine No. 5, 2008, p.25] contains a microcontroller, an information input / output unit, an output key unit, a power supply, terminals for connecting protected zones, terminals for connecting sirens and restriction nodes current for each zone, the input / output node of the information is connected to the microcontroller using the first group of inputs and outputs, the second group of outputs of the microcontroller is connected to the inputs of the output key node, the outputs of which are connected to the terminals for connecting sirens, microcontroller power supply connected to the first output of the power supply, to the second output of which is connected to the power output node output keys. The current limiting nodes for each zone are made on two resistors with a significant current limitation in the loop circuit of each zone. The terminals for connecting the loop cable from which the detectors are powered are connected to the second output of the power supply unit.

A disadvantage of the known control and reception device is its low noise immunity, which is due to the high impedance of the input circuits of the device to which the cables of the corresponding zones are connected, as well as the fact that the detectors are connected only in a 4-wire circuit, when an additional pair of wires is used to power the detectors. In addition, on the signal conductors of the loop there is a low voltage supply of the microcontroller (5 V), from which the detectors cannot be powered, which usually requires a significantly higher voltage (10-30 V) and a significant current to ensure the “FIRE” status of the detectors.

The control and reception device is also known [patent of Russia for the invention No. 2238591 "Fire and security alarm system", IPC G08B 25/00, publ. October 20, 2004] with a controller, an information input / output unit, a power supply, terminals for connecting protected zones, terminals for connecting sirens, and a current limiting unit in the zone. Coordination nodes are used for each detector, and all detectors are connected in parallel to one 2-wire loop, the supply voltage of which is supplied from the power supply terminals of the controller through a resistor. The controller is made on microcircuits that allow power supply from voltages, providing an overlap of the operating voltage range of the detectors (10-20 V). In addition, to analyze the status of the detectors, the device generates periodic pulses of the voltage of the detectors.

The disadvantage of such a control panel is low noise immunity, which is due to the fact that the connection of detectors is carried out only to one zone. In addition, there is a significant dependence of the voltage in the loop on the number of detectors used. This becomes especially significant when the short circuit current is limited to less than 50 mA. And the pulses of the analysis of the state of the detectors formed by the device in the alarm loop only increase the likelihood of false alarms of the detectors in such a fire alarm loop.

Closest to the invention is a control fire detector selected as a prototype [Fire control and fire detector "Warta 1/832", TU 3 of Ukraine 7183.012 92, AKPI.425513.004PS, http://www.chelmash.com.ua] having a microcontroller, an information input / output node, an output key node, a power supply, a multiplexer, controlled current limiting nodes for each zone, terminals for connecting protected zones, terminals for connecting sirens, an information input / output node connected to the microcontroller using first group of inputs and outputs ov, the second group of outputs of the microcontroller is connected to the inputs of the output key assembly, the outputs of which are connected to the corresponding terminals for connecting sirens, the first power output of the microcontroller is connected to the first output of the power supply, the second output of which is connected to the power output of the output key assembly and multiplexer, the analog output of which connected to the analog input of the microcontroller, the third group of outputs of which is connected to the corresponding control inputs of managed restriction nodes current in each zone, the outputs of the controlled nodes of the current limitation, respectively, with the zones are connected to the first group of terminals for connecting protected zones, the fourth group of outputs of the microcontroller is connected to the control inputs of the multiplexer, the analog inputs of which are connected respectively to the first terminals of the measuring resistors, and the first terminals of the power supply are controlled current limiting nodes are interconnected and connected to the third output of the power supply, the common bus of which is connected to the second terminals of the power supply I microcontroller output node keys multiplexer controlled current limiting units and second terminals of the measuring resistor. The analog inputs of the multiplexer are connected to a second group of terminals for connecting zones. The controlled current limiters are made on the basis of three bipolar transistors according to a typical scheme.

The disadvantage of such a fire alarm device is the low noise immunity, which is due to the fact that it contains resistors for monitoring the current in the loops of the corresponding zones, the voltage drop on which reduces the voltage stability between the first and second groups of terminals for connecting the zones from which the detectors are powered. In addition, an EMF of electrical noise is generated on these resistors with respect to the common bus, which is usually grounded.

The basis of the invention is the task of increasing the noise immunity of the device, increasing the stability of the power supply voltage of the detectors, the formation of such a circuit for connecting zones, when the second group of terminals for connecting zones has direct contact with the common ground bus of the device. At the same time, the entire range of possible current values in the signal loop from each zone should go to the analog input of the microcontroller.

The problem is solved in that the fire alarm control unit has a microcontroller, an information input / output unit, an output key unit, a power supply unit, a multiplexer, controlled current limiting units for each zone, terminals for connecting protected zones, terminals for connecting sirens, a node input / output information is connected to the microcontroller using the first group of inputs and outputs, the second group of outputs of the microcontroller is connected to the inputs of the output key node, the outputs of which are connected to the corresponding terminals and for connecting sirens, the first power output of the microcontroller is connected to the first output of the power supply, the second output of which is connected to the power supply node of the output keys and the multiplexer, the analog output of which is connected to the analog input of the microcontroller, the third group of outputs of which is connected to the corresponding control inputs of the controlled restriction nodes current in each of the zones, the outputs of the controlled nodes current limiting respectively with the zones connected to the first group of terminals for connection of the stored zones, the fourth group of outputs of the microcontroller is connected to the control inputs of the multiplexer, the analog inputs of which are connected respectively to the first terminals of the measuring resistors, and the first power leads of the controlled current limiting nodes are interconnected and connected to the third output of the power supply, the common bus of which is connected to the second terminals power supply of the microcontroller, the output key assembly, the multiplexer, the controlled current limiting assemblies and other outputs of the measuring resistor in which it characterized in that a current limiting managed nodes contain additional mirrored current outputs are connected to inputs of an analog multiplexer and a second group of terminals for connection zones connected to the power supply common bus. And each of the controlled current limiting nodes is made up of three transistors, the collector of the first of which is connected to the output of the controlled current limiting node, the emitter of the first transistor is connected through the first resistor to the first power supply of the controlled current limiting node, to which the first conclusions of the second and third resistors are connected, the base of the first transistor is connected to the base of the second transistor, the first terminal of the fourth resistor and the cathode of the diode, the anode of which is connected to the second terminal of the second resistor, the second The third output terminal of the third resistor is connected to the emitter of the second transistor, the collector of which is connected to the additional mirror output of the controlled current limiting unit, the second power output of which is connected to the emitter of the third transistor, the collector of which is connected to the second output of the fourth resistor, and the base is connected to the input through the fifth resistor control of a controlled current limiting node.

In the proposed instrument, a control and firefighter due to the use of controlled current limiting units with an additional mirror current output and its connections with other elements of the device provides improved noise immunity of the device. This scheme allows the use of grounding of one of the wires of the fire alarm loop of each zone. Due to the use of controlled current limiting units with an additional mirror current output, it is possible to reproduce signals proportional to the current in the circuit of each zone on the analog input of the microcontroller relative to the common bus of the power supply unit without using measuring resistors in the fire alarm loop circuit, as is done in the prototype. The detectors that are connected to the corresponding zones are supplied with a stable voltage, which practically does not depend on the number of detectors within the values allowed by the regulatory document - DSTU EN 54-2: 2003 for non-addressed zones.

The figure 1 presents the block diagram of the device reception and control firefighter.

The figure 2 presents the electrical circuit diagram of the controlled node current limitation.

The fire alarm control panel (see figure 1) contains a microcontroller 1, an information input-output node 2, an output key node 3, a power supply unit 4, a multiplexer 5, controlled current limiting nodes 6 for each zone, a first group of terminals 7 for connection protected zones, the second group of terminals 8 for connecting zones, measuring resistors 9 and a group of terminals 10 for connecting sirens. Managed nodes 6 current limits for each of the zones consist of a first transistor 11, a first, second and third resistors 12, 13, 14, a diode 15, a second transistor 16, a fourth resistor 17, a third transistor 18 and a fifth resistor 19.

The input / output node 2 of the information is connected to the microcontroller 1 using the first group of inputs and outputs, the second group of outputs of the microcontroller 1 is connected to the inputs of the node 3 of the output keys, the outputs of which are connected to the group of terminals 10 for connecting sirens. The first power output of microcontroller 1 is connected to the first output of power supply unit 4, the first output of which is connected to the first power supply of node 3 of output keys and multiplexer 5. The third group of outputs of microcontroller 1 is connected to the corresponding control inputs of managed nodes 6 of current limitation in each of the zones. The outputs of the controlled nodes 6 current limits, respectively, with the zones connected to the first group of terminals 7 for connecting protected areas. The first power leads of the controlled current limiting nodes 6 are interconnected and connected to the third output of the power supply unit 4, the common bus of which is connected to the second power outputs of the microcontroller 1, the output key node 3, the multiplexer 5 and the controlled current limiting nodes 6 for each of the zones, and also to the second group of terminals 8 for connecting zones. The first conclusions of the measuring resistors 9 are connected to the analog inputs of the multiplexer 5 and additional mirror outputs of the controlled nodes 6 of the current limit for each of the zones. The second terminals of the measuring resistors 9 are connected to the common bus of the power supply unit 4 and to the second group of terminals 8 for connecting the zones. The analog output of the multiplexer 5 is connected to the analog input of the microcontroller 1, the fourth group of outputs of which is connected to the control inputs of the multiplexer 5.

Each of the controlled nodes 6 current limitation is made on three transistors 11, 16, 18. The collector of the first transistor 11 is connected to the output of the controlled node 6 current limits, the emitter of the first transistor 11 through the first resistor 12 is connected to the power supply of the controlled node 6 current limitation, to which connected the first terminals of the second and third resistors 13 and 14. The base of the first transistor 11 is connected to the base of the second transistor 16, the first terminal of the fourth resistor 17 and the cathode of the diode 15, the anode of which is connected to the second terminal of the second second resistor 13. The second terminal of the third resistor 14 is connected to the emitter of the second transistor 16, whose collector is connected to an additional output mirror 6 managed node current limiting. The second power terminal of the controlled current limiting node 6 is connected to the emitter of the third transistor 18, the collector of which is connected to the second terminal of the fourth resistor 17, and the base is connected through the fifth resistor 19 to the control input of the controlled current limiting node 6.

The device control fire works as follows. After connecting the input voltage to the power supply unit 4, the corresponding voltages supplied to the microcontroller 1, the node 3 of the output keys, the multiplexer 5 and the power leads of the controlled nodes 6 of the current limit appear at its outputs. The microcontroller 1 begins to execute the work program according to the developed algorithm for the operation of the device and the configuration of the control and firefighter device introduced by the maintenance personnel in accordance with the guarded object. At the beginning of the program, the device self-tests. The results of the self-test are reproduced by the node 2 input-output information. If the test is completed with positive results, and the status of the protected zones corresponds to the configuration of the device, which is stored in the non-volatile memory of microcontroller 1, then the device goes into standby mode.

In the standby mode, the microcontroller 1 reproduces the display of this state by the information input / output unit 2 and expects changes that may occur due to the introduction of new information by the operator through the information input / output unit 2. In addition, the microcontroller 1 reproduces the configuration of the device by creating logical signals on the second and third groups of its outputs, which are fed to the output key node 3, as well as to the control inputs of the current limiting nodes 6. The corresponding output keys of the output key assembly 3, as well as the transistors 11, 16 and 18 of the controlled current limiting assembly 6, will be opened or closed. If, according to the configuration of the device, some zones should be disabled, then the low potential levels are set at the corresponding outputs of the third group of outputs of the microcontroller 1, so the corresponding transistors 11, 16 and 18 of the controlled current limiting unit 6 will be closed. There will be no current in the signal loop circuit that is connected to the corresponding terminals 7 and 8. There will be no current in the collector circuit of the second transistor 16. Therefore, there will be no voltage on the corresponding resistors 9 relative to the common bus of the power supply unit 4. On the fourth group of outputs of the microcontroller 1, the state changes, which allows you to alternately connect the resistors 9/1, ..., 9 / N with the analog input of the microcontroller 1 using multiplexer 5. If an alarm loop is not connected to the corresponding pair of terminals 7 and 8, or in the circuit of this the loop is open, then the collector current of the corresponding first transistor 11 of the controlled node 6 current limitation will be absent. The voltage drop across the first resistor 12 will only be caused by the base current of the first transistor 11, and it will be negligible. For this reason, the second transistor 16 will be practically closed.

In standby mode, the current in the signal loop circuit consists of the sum of the consumption currents of all detectors connected to it and the current through the end resistor of the signal loop. To meet the requirements of regulatory documents for the organization of signaling loops, such as a series of European standards EN 54, or Russian GOST R 53325, the current through the terminal resistor of the fire alarm loop must exceed the limit value of the open circuit recorded in the non-volatile memory of microcontroller 1, which, in its first of all, it must exceed the total current consumption of the maximum number of detectors that can be connected to one zone. Typically, the current consumption of modern fire detectors does not exceed 0.1 mA. The maximum number of conventional detectors that connect to one zone, in accordance with EN 54, is 32 pcs. Thus, the current in standby mode for a zone with active detectors can have a value of (4-8) mA, depending on the number of detectors connected to this zone. And the limiting value of the breakage current can be (3-4) mA. In the “FIRE” state, the current in the signal loop circuit can increase by (5-15) mA. Thus, the physical limitation of current by the first transistor 11 during a short circuit between the corresponding pair of terminals 7 and 8 can begin with a value greater than 20 mA. If at maximum current the voltage drop at the first resistor 12 is no more than (10-15)% of the voltage at the third output of the power supply, then we can assume that the detectors will be powered from standby voltage from the stable voltage, because the total voltage drop at the first transistor 11 and first resistor 12 will be negligible. The choice of the ratio of resistors 12 and 14 determines the conversion coefficient of the collector currents of transistors 11 and 16. The resistance of the measuring resistors 9/1, ..., 9 / N, and the range of possible voltage values on these resistors must comply with the technical documentation for microcontroller 1 with respect to the analog input.

The second and fourth resistors 13 and 17 with a diode 15 form a voltage divider that reproduces the potential at the bases of transistors 11 and 16, necessary for their opening with a corresponding current limitation in the collector circuits of these transistors. The diode 15 provides temperature stabilization of the conversion of the collector currents of the transistors 11 and 16. The fifth resistor 19 performs the function of forming the base current of the third transistor 18.

The microcontroller 1 analyzes the current state in the zones and if these changes acquire critical values, changes the display state on the information input-output node 2, and also, if necessary, the state on the corresponding terminals 10/1, ..., 10 / N for connecting sirens.

Resuming the initial state of the standby mode of operation of the device is possible after resuming the state of the zones in standby mode, and the operator performs a reset operation from node 2 input-output information at the appropriate access level, as defined by regulatory requirements.

Due to the use of the controlled node 6 current limitation with an additional mirror current output, as well as its connections with other elements of the device provides improved noise immunity of the device. This scheme allows the use of grounding one of the wires of the fire alarm loop of each zone and the organization of alarm loops as constant current loops in the range of values about (4-20) mA. The use of shielded alarm loops when the loop screen and one of its conductors are grounded from the receiving and control firefighter device allows (see G. Ott “Methods for suppressing noise and interference in electronic systems” M. Mir, 1979, p. 56) significantly improve the noise immunity of the fire alarm system. In addition, the detectors that are connected to the corresponding zones in standby mode are supplied with a stable voltage, which practically does not depend on the number of detectors within the limits allowed by the regulatory document DSTU EN 54-2: 2003.

Claims (2)

1. The fire alarm control unit has a microcontroller, an information input / output node, an output key node, a power supply unit, a multiplexer, controlled current limiting nodes for each zone, terminals for connecting protected zones, terminals for connecting sirens, an information input / output node connected to the microcontroller using the first group of inputs and outputs, the second group of outputs of the microcontroller is connected to the inputs of the output key node, the outputs of which are connected to the corresponding terminals for connecting sirens, first The microcontroller’s power output terminal is connected to the first output of the power supply unit, the second output of which is connected to the power output of the output key assembly and the multiplexer, the analog output of which is connected to the analog input of the microcontroller, the third group of outputs of which is connected to the corresponding control inputs of the controlled current limiting units in each zone , the outputs of the controlled nodes of the current limitation in accordance with the zones are connected to the first group of terminals for connecting protected zones, the fourth group exits the microcontroller’s door is connected to the control inputs of the multiplexer, the analog inputs of which are connected respectively to the first terminals of the measuring resistors, and the first power leads of the controlled current limiting nodes are connected to each other and connected to the third output of the power supply, the common bus of which is connected to the second power leads of the microcontroller, the output node keys, multiplexer, controlled current limiting nodes and with second terminals of measuring resistors, characterized in that we control e current limiting components comprise additional mirrored current outputs are connected to inputs of an analog multiplexer and a second group of terminals for connection zones connected to the power supply common bus. 2. The fire alarm control device according to claim 1, characterized in that each of the controlled current limiting nodes is made up of three transistors, the collector of the first of which is connected to the output of the controlled current limiting node, the emitter of the first transistor is connected to the first power output through the first resistor a controlled current limiting node to which the first terminals of the second and third resistors are connected, the base of the first transistor is connected to the base of the second transistor, the first terminal of the fourth resistor and the cathode of the diode, and the node of which is connected to the second terminal of the second resistor, the second terminal of the third resistor is connected to the emitter of the second transistor, the collector of which is connected to an additional mirror output of the controlled current limiting node, the second power terminal of which is connected to the emitter of the third transistor, the collector of which is connected to the second terminal of the fourth resistor, and the base is connected through the fifth resistor to the control input of the controlled current limiting node.