CS212380B1 - Optical Signal Circuit Connection - Google Patents

Abstract

The invention relates to the field of security, in particular fire alarm. Several detectors are used to protect against fire in large areas and it is required that the detector, activated by fire fumes, optically signal its status. It is advantageous to ensure parallel signaling of the activated detector also in another place, e.g. outside the protected area, in the control room, etc. In the case of activation of several detectors, the problem is that the control panel that supplies the detectors is current-limited and that it is necessary to use larger cross-sections of the connecting wires. The above problem can be solved according to the invention by obtaining the energy for parallel optical signaling from a capacitor powered by a pulsating voltage, which is charged or discharged via an optical element using a transistor. The circuit according to the invention can be used wherever the element of intermittent optical signaling is powered from a remote source of pulsating voltage.

Description

The invention relates to the connection of an optical signaling circuit used as parallel to the internal optical signaling in a fire detector where it is expedient to signal the activation of the detector not only directly there, but also at other places, eg over doors, in corridors, etc.

In known fire alarm systems consisting of a control panel, supplementary circuits and a set of fire alarms, ie sensors of some of the characteristic fire characteristics - smoke, temperature rise, flames, etc., the optical alarm is performed so that at least one of the whole alarm condition the detector on the supply and evaluation loop signals fire, the panel, after evaluating this state, starts to feed the entire loop with the detectors instead of the original constant voltage pulse voltage, where higher pulse amplitude is equal to the original DC voltage, lower amplitude is the duty cycle higher to the lower part of the pulse voltage is usually less than one - to achieve a good perception of intermittent signaling, optical or acoustic. The optical signaling element in the activated detector flashes to indicate not only the fire condition, but also detects the activated detector in a number of detectors on the loop. When an additional optical signaling element, such as a light bulb, LED, etc., is connected, its considerable current consumption causes a decrease in the pulse voltage amplitude on the loop, which significantly reduces the brightness and thus the efficiency of the optical signaling. To reduce this phenomenon, the fire detector loop guides are built from large cross-section wires, resulting in a large loss of expensive copper. Disturbing voltage drops during the current flow through the optical signaling element also occur on the internal resistance of the source. The necessary minimum cross-sections of copper conductors and maximum loop lengths are then prescribed to ensure the optical signaling function.

The above mentioned drawbacks eliminate the connection of the optical signaling circuit, which is based on the charging and discharging of the capacitor in the circuit and thus the accumulation of energy at the time of higher amplitude of the voltage pulse and its use for powering the optical signaling element at the time of lower amplitude of the voltage pulse.

The circuitry according to the invention has several advantages over the prior art. In particular, it allows to extend the length of the loop line several times and thus increase its resistance, or to reduce the cross-section of the line several times to save valuable material - me3, without compromising the optical signaling function. When charging the capacitor, current can be reduced at a time of higher pulse amplitude, while discharging can achieve a higher current for the optical signaling element and thus increase its brightness, which is not dependent on the loop resistance.

The drawing shows the wiring diagram of the optical signaling circuit as it is connected in parallel to the fire detector.

The circuit of the optical signaling circuit is formed in such a way that the positive terminal 1 is connected to the anode of the diode 6, the base of the transistor 6 and through the resistor 2 is connected to the negative terminal 2 which is connected to the negative electrode of capacitor 4 and negative pole of the optical signaling member The diode 6 is connected to the emitter of the transistor 6 and the positive electrode of the capacitor 4. The collector of the transistor 6 is then connected to the positive pole of the optical signaling element 6.

the charging time of the capacitor 4 is determined by its capacitance and the resistances of the source, line, detector diodes and diodes connected in series. It is chosen at least three times less than the time of the higher amplitude of the supply voltage pulse to charge the capacitor 4 to at least 95% of the final voltage value, the discharge constant being given by the product of the capacitance and series parallel resistance of the emitter and collector. 6 and resistance χ. It is chosen to be shorter than the time of the lower amplitude of the supply voltage pulse in order to close the transistor 6 during this time.

The operation of the optical signaling circuit can be divided into three. In the first interval, identical to the time of the higher amplitude of the supply voltage pulses, the transistor 2 is closed and the current flowing from the control panel to the loop and the fire detector flows through the resistor 2 in the circuit and charges the capacitor £ to maximum. In the second interval, by shorter than the time of the lower amplitude of the supply voltage pulse, the capacitor 6 discharges through the open transistor 5, and the optical signaling member 6 such as a bulb, LED or the like that illuminates initially strongly and later brightness decreases exponentially. The discharge current and hence the brightness can be influenced by the choice of capacitor 8 and resistor 2. In the third interval lasting for the rest of the time of the lower amplitude of the supply voltage pulse, the transistor 2 closes and the voltage at capacitor 8 is kept constant and lower pulse. After the three intervals, the entire charging and discharging process and the intermittent signaling of the optical element are repeated.

The optical signaling circuit according to the invention can be used wherever the intermittent optical signaling element, such as a light bulb, LED, etc., is supplied from a remote pulse voltage source, and thereby generates disturbing voltage drops on the long line and internal resistance of the source, brightness of the optical element at the time of its illumination. It is possible to use it not only in electric fire and security signaling, but also in communication technology, industry, transport and so on.

Claims (1)

Optical signal circuit connection, characterized in that the positive terminal (1) is connected to the anode of the diode (3), the base of the transistor (5) and the positive terminal of the resistor (7), the negative terminal (2) is connected to the negative electrode of the capacitor (4). , the negative pole of the optical signaling member (6) and the negative terminal of the resistor (7), the cathode of the diode (3) is connected to the positive electrode of the capacitor (4) and the emitter of the transistor (5); a signaling member (6).