Friday, August 8, 2014
Temperature Monitor Wiring diagram Schematic
A simple op-amp schema that will trigger a relay when a preset temperature is reached. Please note that there is no hysteresis in this schema, so that if the temperature changes rapidly, then the relay may switch rapidly.
Temperature Monitor Circuit Diagram
Temperature Monitor Circuit Diagram
Circuit Notes:
This schema uses an ordinary NTC thermistor with a resistance of 47k at room temperature. A suitable part from Maplin Electronics is FX42V. The schema is set in balance by adjusting the the 47k potentiometer. Any change in temperature will alter the balance of the schema, the output of the op-amp will change and energize the relay. Swapping the position of the thermistor and 47k resistor makes a cold or frost alarm.
Calibration:
At room temperature (25 degrees Celsius) a 47k NTC thermistor resistance is approximately 47k. The non-inverting op-amp input will then be roughly half the supply voltage, adjusting the 47k pot should allow the relay to close or remain open. To calibrate the device, the thermistor ideally needs to be at the required operating temperature. If this is for example, a hot water tank, then the resistance will decrease, one way to do this is use a multimeter on the resistance scale, read the thermistors resistance and then set the preset so that the schema triggers at this temperature.
Please note that if the temperature then falls, the relay will de-energize. If the environment temperatures changes rapidly, then the relay may chatter, as there is no hysteresis in this schema.
Hysteresis, allows a small amount of "backlash" to be tolerated. With a schema employing hysteresis, there will be no relay chatter and the schema will trigger at a defined temperature and require a different temperature to return to the normal state. Hysteresis can be applied to the schema using feedback, try a 1Meg resistor between op-amp output, pin 6 and the non-inverting input pin 2 to give the schema hysteresis.
Without offset null adjustment, the output of the 741 IC will be around 2 Volts (quiescent) swinging to nearly full supply when triggered. The 4.7k and 1k resistor form a potential divder so that under quiescent conditions the transistor will be off. Quiescent or steady state means no signal, or in this case (when the temperature does not cause the output to swing to full voltage)
Calibration:
At room temperature (25 degrees Celsius) a 47k NTC thermistor resistance is approximately 47k. The non-inverting op-amp input will then be roughly half the supply voltage, adjusting the 47k pot should allow the relay to close or remain open. To calibrate the device, the thermistor ideally needs to be at the required operating temperature. If this is for example, a hot water tank, then the resistance will decrease, one way to do this is use a multimeter on the resistance scale, read the thermistors resistance and then set the preset so that the schema triggers at this temperature.
Please note that if the temperature then falls, the relay will de-energize. If the environment temperatures changes rapidly, then the relay may chatter, as there is no hysteresis in this schema.
Hysteresis, allows a small amount of "backlash" to be tolerated. With a schema employing hysteresis, there will be no relay chatter and the schema will trigger at a defined temperature and require a different temperature to return to the normal state. Hysteresis can be applied to the schema using feedback, try a 1Meg resistor between op-amp output, pin 6 and the non-inverting input pin 2 to give the schema hysteresis.
Without offset null adjustment, the output of the 741 IC will be around 2 Volts (quiescent) swinging to nearly full supply when triggered. The 4.7k and 1k resistor form a potential divder so that under quiescent conditions the transistor will be off. Quiescent or steady state means no signal, or in this case (when the temperature does not cause the output to swing to full voltage)
Labels:
circuit,
diagram,
monitor,
temperature
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