Pyroelectric Fire Sensor -Circuit-Diagram. Here is an ultra-sensitive fire sensor that exploits the direct piezoelectric property of an ordinary piezo element to detect fire. The lead zirconate titanate crystals in the piezo element has a property to de-form and generate an electric potential plifier with gate protected p-channel. MOSFETs in the inputs. It has high speed of performance and low input current requirements. There are two inputs—the non inverting input (pin 3) connected to the piezo element through diode D7 (OA71) that carries the volt-age signal from the piezo element and the inverting input (pin 2) that gets a momentarily changes the voltage level at pin 3 of IC1 and its output swings high. Transistor T1 conducts taking the reset pin 12 of IC2 to ground. IC2 is now enabled and start oscillating. With the shown values of the oscillating components C3 (0.22) and R8 (1M), when heated, thus converting the piezo element into a heat sensor.
Pyroelectric Fire Sensor -Circuit-Diagram
The schema we have described here is very sensitive. It gives a warning alarm if the room temperature increases more than 10 degree Celsius. The entire schema is divided into two section—the sensor and the power supply section. Sensor side schema. Fig. 1 shows the fire sensor schema. The front end of the schema has a sensitive signal amplifier built around IC1 (CA3130). It gives a high output when the temperature near the piezo element increases. IC CA 3130 is a CMOS operational am-preset volt-age through VR1.By adjusting VR1, it is easy to set the reference voltage level at pin 2. In normal condition, IC1 gives a low output and the remaining schemary will be in a standby state. Capacitor C2(10P) keeps the non-inverting in-put of IC1 stable, so that even a slight change in voltage level in the inputs can change the output to high.
Normally, IC1 gives a low output, keeping transistor T1 non-conducting. Reseting pin 12 of IC2 (CD4060) connected to the collector of transistor T1 gets a high voltage through R6 and IC2 remains disabled. When the piezo element gets heat from fire, asymmetry in its crystals cause a potential change, enabling capacitor C2 to discharge. It the first output (Q3) turns high after 4 seconds and a red LED starts flashing. If the heat near the piezo persists, Q7 (pin 14) output of IC2 becomes high after 1 minute, and the alarm starts beeping. If heat continues, Q9 (pin15) turns high after four minutes and turns on the relay driver transistor T2. At the same time, diode D8 conducts and IC2 stops oscillating and toggles.The solenoid pump connected to the N/O (normally opened) contact of the relay starts spraying the fire-ceasing foam or water to the possible sites of fire.
Power Supply With Battery Backup Circuit Diagram
Power supply schema. Power sup-ply section (Fig. 2) comprises a 0-12V, 1 A step down transformer with a standard full wave rectifier formed by D1 through D4 and filter capacitor C1. A battery backup is provided if the mains supply cut-off due to short-schema and fire. A 12V, 4.5 Ah rechargeable battery is used for backup to give sufficient current to the solenoid pump.
When mains power is available, diode D5 forward biases. It provides power to the schema and also charges the bat-tery through resistor R2 and it limits the charging current to 120 mA. When power fails, diode D5 reverse biases and diode D6 forward biases, giving instant backup to the schema. LED1 indicates the availability of mains power.Assemble the schema on a common PCB and enclose it in a suitable case. Connect the piezo element to the schema using thin plastic wire. Glue the flat side of the piezo element on a 30x30 cm aluminium sheet to increase its sensitivity. Fix the sheet with the piezo sensor to the site where protection is needed. The remaining schema can be fixed in a suitable place. If only the alarm generator is needed, omit the relay driver section.
Author :D. Mohan Kumar - Copyright : EFYMag
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