RU2032226C1 - Fire alarm - Google Patents

Abstract

FIELD: fire alarm system. SUBSTANCE: loop control unit 5, depending on resistance of loop, forms signals NORMAL or ALARM across outputs of threshold devices 5.4 and 5.5. Signal from output of unit 5 gets to processing unit 6 in which flip-flop 6.5 is set in initial position by means of integrating circuit 6.3, 6.4 at switching on. When normal condition of loop is disturbed, flip-flop 6.5 changes over and switches on generator 6.7 before switching off of device. Signalling relay 9 generates alarm signal which is transmitted to warning system. Under normal conditions relay 9 is de-energized and its contacts are closed. Under alarm conditions contacts of relay make and break periodically. If device is switched on for fire protection, contacts of signalling relay 9 remain closed when power is cut off, and signalling loop is kept under control of warning system. EFFECT: enhanced functional reliability of device. 3 cl, 1 dwg

Description

 The invention relates to a fire alarm technique and can be used to process signals from a signal loop with detectors included in it, implement tactics for taking an object under guard, disarm it, and also issue notifications to local sirens and a notification transmission system.

 A device for alarming is known, comprising an alarm loop, a measuring element, a loop power supply, a control unit, a processing unit, a light annunciator unit, and a signal relay unit with open contacts in a de-energized state and closed when the relay is on.

 The loop power source is connected to the signal loop and the measuring element connected in series. At the end of the loop, a terminal element is installed - a resistor. The current in the loop and the voltage at the measuring element depend on the state of the detectors, the resistance of the loop wires and their leakage resistance.

 The first input of the loop control node is connected to the circuit connecting the measuring element and the alarm loop, the second and third inputs are connected to the loop power source, and the output of the loop control node is to the input of the processing node.

 The loop control node generates a “Normal” or “Alarm” signal at its output, depending on the state of the detectors, resistance parameters of the loop wires and their leakage.

 The processing unit contains the installation circuit in the initial state when the device is turned on, the alarm memory element, and circuits that provide the specified tactics for taking the object under protection and disarming. The output of the processing unit is connected to the input of the light siren unit and the signal relay unit having open contacts in the off state.

 The contacts of the signal relay through the terminal element are connected to the notification system.

 In the security mode, the device provides a constant mode of illumination of the light annunciator at the guarded object and generates a “Normal” signal to the notification transmission system (signal relay contacts are closed).

 The disadvantage of this device is the issuance of an alarm signal to the notification transmission system when the power is turned off or the device malfunctions, regardless of the status of the loop, since this causes a de-energization of the signal relay, the contacts of which open.

 The closest technical solution to the proposed one is an alarm device, which additionally includes a switching unit, which provides a change in the structure of the device depending on the presence or absence of power to the device. This device is taken as a prototype.

 In the presence of power supply, the structure of the device (the composition of the functional blocks and their relationship) is similar to that described.

 When the power is turned off, the switching unit ensures the disconnection of the alarm loop and the notification transmission system from the device nodes and their direct connection with each other.

 The functions of the switching device are usually implemented using one or more relays, through the windings of which current flows from the power supply of the device. When the power is off, the windings are de-energized, the relay automatically switches, providing a direct connection of the alarm loop to the notification system. Thereby, control is achieved by the transmission system of notifications of the status of the alarm loop in the absence of power supply at the facility.

The disadvantage of this device is the low functional reliability due to the following reasons:
1. A reliable change in the structure of the device is achieved only when the power is turned off suddenly. However, a power outage may occur after a prolonged voltage drop or after a series of short interruptions. In these cases, situations are possible when the switching node has not yet worked, or when the switching node is in an intermediate position, a false alarm is already being generated on the notification system;
2. A malfunction of the device (for example, as a result of a failure of a node) leads to a de-energization of the signal relay and the formation of a false alarm signal on the transmission system;
3. The switching unit has many contact groups, the reliability of which is significantly lower than electronic components. A mechanical or electrical failure (for example, due to an increase in contact resistance) of at least one connection causes a false alarm to be generated on the transmission system.

 Since the structure of the device may change, its maintenance is complicated.

 The purpose of the invention is to increase the functional reliability of the device, resulting in an increase in the reliability of protection.

 For this, a connection unit, an inverter and a signal relay with closed contacts in a de-energized state are introduced into the device.

 One terminal of the alarm loop is connected to one terminal of the measuring element and to the first output of the loop control node. The second input of the loop control node is connected to another signal loop terminal, and the output is connected to the input of the processing node. The output of the processing unit is connected to the input of the node of the light siren and inverter. One terminal of the power source is connected to another terminal of the measuring element, the third input of the loop control node and is one output terminal of the device. The signal relay contact is disconnected. The other terminal of the power supply through the connection node is connected to another terminal of the alarm loop and one terminal of the NC contact of the alarm relay. The inverter output is connected to the signal relay coil. The other NC terminal is the other output terminal of the device.

 All elements of which the proposed device is made are well known. The search for information did not reveal any technical solution containing an identical or equivalent set of essential features, therefore, the proposed technical solution meets the criteria of the invention of "Novelty" and "Industrial applicability".

 This proposal solves the problem of increasing the functional reliability of the alarm device. When searching for information, no device made on this element base was found that has the same level of complexity and has functional reliability similar to the reliability of the proposed device. Therefore, this proposal meets the criteria of the invention "Inventive step".

 The drawing shows a structural diagram of the device.

 The device has a signal loop 1, a measuring element 2, a connection unit 3, a loop power supply 4, a loop control unit 5, a processing unit 6, an inverter 7, a light siren unit 8, a signal relay 9 with closed contacts in a de-energized state, a system (communication line ) 10 transmission of notices.

 The device operates as follows.

 The notification transmission system in the general case contains linear sets (by the number of guarded directions) and in each linear set there is a limiting resistor 10.3, a switch 10.2 and 10.1.

 If the direction of the notification transmission system is disarmed, then the switch 10.2 is open and no current flows through the communication line 10. When setting the direction under protection, the switch 10.2 closes and current flows from the source 10.4 of the notification system along line 11, the value of which depends on the resistance of this direction. The current value is analyzed by the amplitude selector of the notification system.

 The alarm loop 1 contains a terminal resistor 1.1 and security detectors. Detectors 1.2 having a normally closed contact are connected in series with the terminal resistor, and detectors 1.3 with a normally open contact are connected in parallel with the terminal resistor. The resistance of the alarm loop in the "Normal" mode is determined by the value of the terminal resistor 1.1, in the "Alarm" mode - by the leakage resistance and the resistance of the loop wires.

 The measuring element 2 is designed to convert the magnitude of the current flowing through the loop into voltage. As a measuring element, for example, a resistor 2.1 can be used, the resistance of which is slightly less than the resistance of the terminal resistor and the maximum possible resistance of the wires of the loop and communication line 11 with the notification transmission system 10. Thus, the measuring element 2 practically does not affect the amount of current flowing through the loop 1. The voltage on the measuring element is determined by the magnitude of the voltage in line 11 and the resistance of the loop 1.

 The loop power source 4 is designed to supply voltage to the loop 1 in the case when the direction of the notification system is disarmed. The voltage value of the source 4 is chosen so that it does not exceed the voltage in the communication line 11 when connecting the direction of the notification system.

 The connection unit 3 provides connection to the loop 1 of the source 4 when the direction of the notification transmission system is disarmed. It may contain, for example, diode 3.1. When the direction of the notification system is connected, the voltage in line 11 exceeds the voltage of the source 4 diode 3.1 prohibition. Thus, the device does not affect the amount of current in line 11 from the notification system.

 The loop control unit 5, depending on the loop resistance, generates “Normal” or “Alarm” signals at its output. It contains threshold devices 5.4 and 5.5, an OR circuit 5.6 and a protection circuit 5.7-5.9 against short-term disturbances of loop conditions.

 The response threshold of devices 5.4 and 5.5 is set by the divider 5.1-5.3 in such a way that a logical "0" signal is generated at the output of device 5.4 if the loop is in the "Normal" state, or if the logical "1" signal is in the "Open" state. At the output of device 5.5, a logical "0" signal is generated if the loop is in the "Normal" state, and the logical "1" signal is in the "Short" state. At the output of the OR circuit 5.6, the logical “0” signal will be, if the loop state is “Normal”, and the logical “1” signal, if the loop state is “Alarm” (the loop is closed or open).

 If the loop state change from “Norm” to “Alarm” and again to “Norm” is short-term, then an alarm signal (logical “0”) is generated at the output of threshold device 5.9 only if the duration of the alarm signal at the output OR 5.6 scheme is greater than a certain threshold value specified by the time constant of the integrating circuit (5.7, 5.8). Thus, the loop control unit 5 unambiguously determines the loop state (with the Norma signals - logical "1" or "Alarm" - logical "0" at the output of the threshold device 5.9) and provides noise immunity to short-term disturbance of the loop state. The response thresholds of devices 5.4 and 5.5 vary in proportion to the supply voltage of the loop 1, therefore, the operation of the control unit 5 does not depend on the magnitude of this voltage.

 From the output of the control unit 5, the loop status signal is sent to the processing unit 6, which provides a given algorithm for the operation of the device. The usual requirements are to implement the tactics of arming “With an open door” and remembering the transition to the “Alarm” state until the device is turned off.

 The processing unit 6 contains a trigger 6.5, a differentiating circuit 6.1, 6.2, an integrating circuit 6.3, 6.4, an OR 6.6 circuit, and a controlled pulse generator 6.7.

 When the supply voltage of the device is turned on, the trigger 6.5 using the integrating circuit 6.3, 6.4 is set to a state in which a logical "1" signal is set on its inverse output. If the alarm loop is open, a logical "0" signal is output from the output of the control unit 5 to the OR 6.6 circuit. At the output of the OR 6.6 circuit, a logical "1" signal is generated, under the action of which the generator 6.7 is turned on.

 If the normal state of the loop is violated, then at the output of the control unit 5, the signal from the state of logical "1" goes into the state of logical "0". Through the differentiating circuit 6.1, 6.2, the logic "0" signal is fed to the S-input of trigger 6.5. The trigger is set to a state in which its inverse output is a logical "0" signal. In the future, before turning off the power to the device, regardless of the state of the loop, the 6.7 generator will be turned on.

 From the output of the processing unit 6, the logical 1 signal in the guard mode or alternating logical 0 and logical 1 signals are sent to the light sire unit 8 and, through the inverter 7, to the signal relay 9, which has closed contacts in a de-energized state.

 The node 8 of the light annunciator contains a relay 8.1 and an indicator 8.2. In the armed mode, when the generator 6.7 is turned off, the logic signal “1” from its output relays 8.1 is maintained in the off state, while the indicator 8.2 lights up. In alarm mode, the indicator blinks.

 The inverter 7 is designed to convert signals from the output of the processing unit 6: in the armed mode, the signal relay receives a logical "0" signal, in alarm mode - alternating signals of a logical "0" and a logical "1".

 Using the signal relay 9 provides the issuance of a notification system signal "Alarm". Thus, the identity of the states of the device and the notification system is achieved. The contacts of the relay 9 are switched off in series with the line 11 of the notification system. In the "Normal" mode (at the output of node 6 - the signal is logical "1"), relay 9 is de-energized and its contacts are closed. In the alarm mode, the relay contacts are periodically opened, which for the notification system is a sign of an alarm signal from the protected object.

 If the device was in the armed mode, then when the power is turned off, the contacts of the alarm relay 9 remain closed and the alarm loop remains under the control of the notification system.

 Thus, in the proposed device provides simultaneous control of the alarm loop by the device and the notification system. The structure of the device does not change depending on the presence or absence of its power supply. A device failure does not cause a false alarm to be generated on the notification system. Thereby, increased functional reliability of the device and, therefore, increased security of protection is achieved.

Claims (3)

 1. DEVICE for ALARM, containing an alarm loop, one terminal of which is connected to one terminal of the measuring element and the first input of the loop control node, the second input of which is connected to the other terminal of the alarm loop, and the output is connected to the input of the processing unit, the output of which is connected to the input light siren assembly, signal relay, loop power supply, one terminal of which is connected to the other terminal of the measuring element, the third input of the loop control node and is one output terminal characterized in that the connection unit and the inverter are inserted into it, the signal relay contact is disconnected, the other power supply terminal is connected through the connection node to another signal loop terminal and one signal relay opening contact terminal, the output of the processing unit is connected to the inverter input, the output which is connected to the winding of the signal relay, the other terminal of the NC contact is the other output terminal of the device.  2. The device according to claim 1, characterized in that the loop control node contains the first and second threshold elements, the signal inputs of the first threshold element and the second threshold element are combined and are the first input of the loop control node, a current-setting voltage divider containing the first resistor, one output which is the second input of the loop control node, and the other is connected to one terminal of the second resistor and the installation input of the first threshold element, the other terminal of the second resistor is connected to one terminal of the third cut the source and the input of the second threshold element, the outputs of the first and second threshold elements are connected to the inputs of the OR element, the output of which is connected to one terminal of the resistor of the integrating circuit, the other terminal of which is connected to one terminal of the capacitor of the integrating circuit and the signal input of the third threshold element, the inverting output of which is the output of the loop control node, the other terminals of the third resistor of the current-setting voltage divider and the capacitor of the integrating circuit are combined and are the third the input of the loop control node.  3. The device according to claim 1, characterized in that the processing unit contains a driver of the installation pulse, the output of which is connected to the R-input of the trigger, the input of the processing unit is connected to one input of the OR element and through a differentiating circuit to the S-input of the trigger, the output of which connected to another input of the OR element, the output of which is connected to the starting input of the pulse generator, the output of which is the output of the processing unit.