A basic resistive temperature sensor, also known as an RTD (Resistance Temperature Detector), is a type of temperature sensor that relies on the principle that the electrical resistance of a material changes with temperature. RTDs are commonly used for accurate and precise temperature measurements in various industrial, scientific, and commercial applications.
The primary function of an RTD is to provide a resistance value that corresponds to the temperature of the environment it's exposed to. Here's how it works:
Principle of Operation: RTDs are typically made from materials that exhibit a predictable and repeatable change in resistance with temperature. The most common material used is platinum (Pt) due to its excellent temperature-resistance relationship. As temperature increases, the resistance of the RTD increases in a relatively linear manner.
Measurement Circuit: An RTD is integrated into an electrical circuit where its resistance can be measured. The most common configuration is a Wheatstone bridge circuit. The bridge consists of the RTD along with three other resistors, forming a balanced bridge arrangement.
Reference Temperature: The bridge circuit is initially balanced by adjusting the other three resistors until the voltage across the bridge is zero at a reference temperature. This is typically done at a specific temperature point, often 0°C or 25°C.
Temperature Measurement: As the temperature changes from the reference point, the resistance of the RTD changes accordingly. This imbalance in resistance causes a voltage to develop across the bridge, which can be measured and related to the temperature using calibration curves or equations provided by the RTD manufacturer.
Signal Processing: The voltage signal generated by the bridge circuit is typically quite small. Signal conditioning and amplification may be required before it can be accurately measured by the data acquisition system or temperature measurement equipment.
Calibration: RTDs need to be calibrated to accurately relate the resistance change to temperature. Calibration involves determining the relationship between resistance and temperature over the intended operating range. This calibration data is then used to convert the measured resistance into an accurate temperature reading.
Accuracy and Precision: RTDs are known for their high accuracy and precision, making them suitable for applications that require precise temperature control and measurement.
In summary, the function of a basic resistive temperature sensor (RTD) is to provide an accurate and repeatable electrical resistance that varies with changes in temperature. This resistance is used to derive temperature readings through a combination of electrical circuitry, calibration, and data processing.