1. Radial lead NTC thermistors: These are glass-encapsulated NTC thermistors with radial leads. They are commonly used in temperature sensing applications such as air conditioning systems, refrigerators, and food processing equipment.
2. Chip NTC thermistors: These thermistors have a small form factor and are suitable for surface mount applications. They are used in various electronic devices where temperature sensing is required.
3. Bead NTC thermistors: These thermistors are designed to be embedded or potted into various materials such as plastics and metals. They are commonly used in automotive and industrial applications.
4. Glass-encapsulated NTC thermistors with axial leads: These are similar to radial lead thermistors, but with axial leads. They are commonly used in high-temperature applications such as ovens, heaters, and industrial machinery.
5. Epoxy-coated NTC thermistors: These thermistors are coated with epoxy for protection against moisture, dust, and physical damage. They are commonly used in outdoor temperature sensing applications.
6. Probes NTC thermistors: These are thermistors with a probe or rod shape, which makes them suitable for immersion in liquids or gases. They are commonly used in food processing, chemical, and pharmaceutical industries.
The choice of thermistor type depends on the specific temperature sensing application requirements.
Q: What are the advantages of using NTC thermistors?
A: NTC thermistors have several advantages including high sensitivity to temperature changes, fast response time, and a low cost.
Q: What are the applications of NTC thermistors?
A: NTC thermistors are commonly used in various temperature sensing applications such as air conditioning systems, refrigerators, heaters, and automotive systems.
Q: What is the accuracy of NTC thermistors?
A: The accuracy of NTC thermistors varies depending on the model and manufacturer. However, high accuracy NTC thermistors can have an error of less than 1% over a wide temperature range.
Q: How do you select an NTC thermistor?
A: When selecting an NTC thermistor, consider the desired temperature range, accuracy requirements, and application-specific factors such as the required response time and environmental conditions.
7. What is the operating temperature range for NTC thermistors?
The operating temperature range for NTC thermistors varies depending on the model and manufacturer. However, high-temperature NTC thermistors can operate up to 1000°C.
8. Can NTC thermistors be used for measuring humidity?
While NTC thermistors are not designed for measuring humidity, they can be used in conjunction with other sensors to measure humidity indirectly. If you are looking for NTC humidity sensor, welcome to contact us.
NTC thermistors are available in a wide range of configurations; typical ones include glass-encapsulated diodes, leads with resin coatings, and SMD variants. When temperature protection on PCB boards is necessary, SMD NTC thermistors based on multi-layer technology are the best option.
A very basic temperature sensor that is widely used in consumer electronics is the NTC thermistor. A common example of a temperature-sensitive semiconductor resistor is the NTC thermistor, whose resistance value drops incrementally as temperature rises. NTC thermistors are made of mixed oxide polycrystalline ceramics. For various events, different packaging of various materials are employed.
Negative Temperature Coefficient is referred to as NTC. The resistance of NTC thermistors reduces as temperature rises because they have a negative temperature coefficient. They are generally employed as current limiters and resistive temperature sensors. A silicon temperature sensor's (silicon oxide) temperature sensitivity coefficient is around five times higher than a resistance temperature detector's, which is ten times higher (RTD). NTC sensors are frequently employed between -55°C and 200°C.
The phrase "thermistor phenomena" and "material with a negative temperature coefficient that declines exponentially with temperature rise" refer to negative temperature coefficient (NTC) thermistor, respectively. The finished product, a semiconductor ceramic, is created by thoroughly combining, shaping, and sintering two or more metal oxides, including those of manganese, copper, silicon, cobalt, iron, nickel, and zinc.