PTC Thermistor
Description | Unit Price Unit Pack |
Stock Info | |||
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50.840.80H540 S Platinum Heater Part No.: WPTC877 package: THT Packaging: TRAY |
Unit Price
18.63 $
Unit Pack
10
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Stock Info
12 weeks
On request
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Price, Lead time Datasheet |
PTC Thermistor - More information
PTC thermistors, also known as Positive Temperature Coefficient thermistors, are electronic components that exhibit an increasing resistance with rising temperature. This property makes them particularly valuable in applications requiring temperature monitoring or control. Unlike NTC thermistors, which have a decreasing resistance with increasing temperature, PTC thermistors offer unique advantages in protection and control electronics. The development of PTC thermistors dates back to the mid-20th century, and they have since become indispensable components in electronics.
PTC thermistors are used in numerous fields, including the automotive industry, medical technology, industrial controls, and consumer electronics. Their main advantages include self-regulation capability and high reliability. However, there are also some drawbacks, such as sensitivity to rapid temperature changes and the need for specific operating voltages.
How a PTC Thermistor Works
PTC thermistors are based on the principle of a positive temperature coefficient, where the material's resistance increases with rising temperature. This property is achieved using special materials like barium titanate, which have a specific crystal structure that responds to temperature changes. These materials are often used in ceramic form, providing high stability and reliability. As the temperature of a PTC thermistor increases, the mobility of charge carriers decreases, leading to higher resistance. This effect is due to the reaction of the crystal structure to thermal energy, reducing the density of free charge carriers.
A crucial aspect of the operation of PTC thermistors is self-heating. When current flows through the thermistor, it generates heat due to its electrical resistance. This heat further increases the thermistor's temperature, leading to a further increase in resistance. This effect can be utilized to achieve a self-regulating function where the thermistor limits the current flow to prevent overheating. The temperature coefficient, which describes the ratio of resistance change to temperature change, is a critical parameter for a PTC thermistor's performance. This coefficient is determined by the material composition and manufacturing processes.
Other important characteristics of a PTC thermistor include its response speed and stability over a wide temperature range. The thermal mass and specific heat of the materials used affect the response time, while the chemical purity and crystal structure determine the long-term stability. A well-designed PTC thermistor provides reliable and precise temperature control in various applications.
Types and Forms of PTC Thermistors
There are different types of PTC thermistors, including cold conductors and hot conductors. Cold conductors or PTCs are more conductive at low temperatures and increase their resistance with rising temperature. This property makes them ideal for applications requiring overcurrent protection, as they abruptly limit the current flow at a certain temperature. Hot conductors, on the other hand, have a higher resistance at higher temperatures and are used in applications requiring continuous temperature monitoring.
PTC thermistors are available in various sizes and package forms, including SMD (Surface-Mount Device) types that are well-suited for use in compact electronic devices. The choice of size and package depends on the specific application requirements, such as available space, electrical requirements, and heat dissipation. SMD thermistors offer the advantage of easy integration into automated manufacturing processes and high packing density on circuit boards.
Ceramic and silicon-based PTC thermistors offer different properties. Ceramic types, often made from materials like barium titanate, provide high temperature resistance and are robust against mechanical stress. They are ideal for applications in harsh environments and at high temperatures. Silicon-based PTC thermistors, on the other hand, offer higher accuracy and better repeatability of resistance values, making them suitable for precise temperature measurements and control.
Selecting the right PTC thermistor for an application requires careful analysis of operating conditions and desired properties. Factors such as response time, long-term stability, rated voltage, and size must be considered to ensure optimal performance.
Key Parameters and Specifications
The key parameters of a PTC thermistor include the resistance curve, minimum resistance, nominal resistance, and tolerance. The resistance curve describes how the thermistor's resistance changes with temperature, while the minimum resistance indicates the lowest resistance value the thermistor reaches at a specific temperature.
The nominal resistance is the resistance value at a defined reference temperature, often 25°C. Tolerance indicates the allowable deviation from this value. Other important parameters are the temperature range within which the thermistor operates reliably and the transition temperature at which the resistance increases sharply. Long-term stability and response times are also crucial specifications that describe the thermistor's reliability and response speed.
Applications and Use Cases of PTC Thermistors
PTC thermistors are used in a variety of applications requiring protection against overcurrent and overheating. In the automotive industry, they are commonly used in heating systems such as seat heaters and defrosters, providing reliable temperature control. They are also used to monitor battery temperature in electric vehicles to ensure the safety and efficiency of the battery.
In medical technology, PTC thermistors control temperature in devices like incubators and blood warmers, where precise and reliable temperature control is crucial to ensure the safety and effectiveness of medical devices. PTC thermistors offer fast response times and high reliability, which are essential for critical applications.
Industrial applications include the use of PTC thermistors in motor controls, where they act as overcurrent protection by limiting the current when the temperature exceeds a certain threshold. In power supplies, they prevent overheating by reducing current flow in the event of excessive heat generation. These protection mechanisms are critical to preventing damage and failures in industrial systems.
The ability to measure and monitor temperature accurately makes PTC thermistors indispensable in consumer electronics and HVAC systems. In consumer electronics like TVs and computers, they protect against overheating and improve the reliability and lifespan of the devices. In HVAC systems, they provide efficient temperature control and contribute to energy savings.
The wide range of applications of PTC thermistors demonstrates their versatility and importance in modern electronics. Their ability to reliably respond to temperature changes and provide protective functions makes them indispensable components in many critical systems and applications.
Manufacturing Process and Materials
The production of PTC thermistors starts with selecting suitable materials, such as ceramics or silicon, optimized for specific temperature coefficients. These materials are shaped into small components and encapsulated in housings that protect them from environmental influences.
The manufacturing process includes several stages of quality control to ensure that the thermistors meet the required specifications. Tests for temperature stability, resistance accuracy, and long-term reliability are crucial for the quality of the finished products. New developments in material research, such as the use of platinum and polymers, contribute to improving the performance and reliability of PTC thermistors.
Integration and Design-In of PTC Thermistors
Integrating PTC thermistors into electronic circuits requires careful planning and design-in processes. Recommendations for integration include considering the ambient temperature, selecting the right size, and ensuring sufficient ventilation to avoid self-heating.
Practical examples show how PTC thermistors have been successfully integrated into various applications to provide overcurrent and overheating protection. Best practices include close collaboration with manufacturers and the use of detailed technical datasheets to ensure optimal thermistor performance.
Rutronik as a Partner for PTC Thermistors
At Rutronik, we offer a comprehensive product portfolio and customized solutions for PTC thermistors. Our technical expertise and consulting services support you in selecting and integrating the right thermistors. Success stories and customer references testify to our competence and reliability. Contact us for more information and benefit from our experience and innovative solutions. Rutronik is the ideal partner to meet your PTC thermistor requirements and successfully implement your projects. With over 25% delivery share, passive components are one of the pillars of our supply chain. Smooth delivery is crucial, especially here. Many part numbers with high delivery volumes but relatively low sales are prone to errors and present a logistical challenge. We excel in this area with special logistics systems and IT connections.
We understand the importance of quality and reliability in electronic components and are your ideal partner for electrolytic capacitors. With our deep understanding of specific application requirements and our commitment to technological excellence, we are ready to support you with all your needs.