What is the Difference Between Thermocouple and Thermistor?
🆚 Go to Comparative Table 🆚The main difference between thermocouples and thermistors lies in their working principles and sensing factors. Here are the key differences between the two:
- Temperature Sensing Parameter: In thermocouples, the variation in temperature creates a voltage between two dissimilar metals, while in thermistors, the resistance changes with temperature variations.
- Material: Thermocouples are made from metal or alloys, while thermistors are made from semiconductor materials or oxides of magnesium, nickel, or cobalt.
- Accuracy: Thermocouples have high accuracy over a wide range of temperatures, including extreme temperatures. In contrast, thermistors have excellent accuracy in mid-range temperature measurement, but their accuracy falls abruptly above or below this range.
- Sensitivity: Thermistors are very sensitive due to their non-linear characteristic curve, providing a high level of sensitivity. Thermocouples are less sensitive compared to thermistors.
- Linearity: Thermistors have a non-linear response, while thermocouples have a mostly linear response to temperature changes.
- Power Source: Thermistors are passive sensors that require a power source to convert their resistance into an electrical signal. Thermocouples are active sensors that do not require a power source.
When choosing between a thermistor and a thermocouple as a temperature sensor, factors such as temperature range, stability, accuracy, and application should be considered.
On this pageWhat is the Difference Between Thermocouple and Thermistor? Comparative Table: Thermocouple vs Thermistor
Comparative Table: Thermocouple vs Thermistor
Here is a table comparing the differences between thermocouples and thermistors:
| Feature | Thermistor | Thermocouple |
|---|---|---|
| Definition | A thermally sensitive resistor that exhibits a continuous, small, incremental change in resistance correlated to temperature variations. | A temperature measurement device made from two different metals or alloys that generate a voltage proportional to the temperature. |
| Working Principle | Resistance change with temperature variation. | Voltage generation due to the junction of two different materials with temperature variation. |
| Measuring Range | -50°C to 250°C. | -200°C to 1200°C. |
| Accuracy | High sensitivity, can detect small variations in temperature. | Less accurate than thermistors, but still suitable for many applications. |
| Response Time | Quick response compared to thermocouples. | Slower response time compared to thermistors. |
| Material | Made from semiconductor materials or oxides of magnesium, nickel, or cobalt. | Made from two different metals or alloys. |
| Power Source | Requires a power source to convert resistance into an electrical signal. | Does not require a power source, as it generates its own voltage. |
| Linearity | Non-linear resistance versus temperature curve. | Linear voltage versus temperature curve. |
| Applications | Commonly used in life safety applications like fire detectors and thermometers. | More often used in industrial settings due to their durability and lower cost. |
Both thermistors and thermocouples are suitable for different temperature sensing applications, and the choice between them depends on factors such as accuracy, response time, and the specific application.
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