The Taconic CER-10 is a high-quality material specifically designed for electronic applications. It offers a range of desirable properties that make it suitable for various uses in the electronics industry.
Taconic CER-10 is known for its exceptional thermal stability, allowing it to withstand high temperatures without softening or losing its structural integrity. This thermal resilience makes it well-suited for applications where exposure to harsh environments or elevated temperatures is expected.
Why Taconic CER-10 So is Important In Electronic Device?
One of the notable features of Taconic CER-10 is its increased flexural strength. This property enables it to withstand bending and mechanical stress, making it ideal for applications that involve frequent handling or mechanical forces.
Additionally, Taconic CER-10 facilitates circuit board miniaturization, which is crucial in modern electronic designs where space optimization is essential. The material’s dimensional stability helps maintain precise geometries and alignment of components, ensuring reliable electrical performance.
Taconic CER-10 exhibits low moisture absorption, reducing the risk of performance degradation caused by moisture ingress. Its low Z-axis expansion further contributes to dimensional stability and reliable operation by minimizing changes in size and shape due to temperature variations.
Manufactured with expertise by companies like JarnisTech, Taconic CER-10 offers exceptional interlaminar bond, ensuring strong adhesion between layers and enhancing the overall reliability of the material.
Overall, Taconic CER-10 is a premium material that combines thermal stability, flexural strength, dimensional stability, and other advantageous properties, making it a preferred choice for demanding electronic applications.
Is Taconic CER-10 suitable for High-frequency PCBs?
Yes, Taconic CER-10 is suitable for high-frequency PCBs. CER-10 is a high-performance ceramic-filled PTFE material that offers excellent electrical properties, including low dielectric loss and low signal loss at high frequencies. It has a high glass transition temperature (Tg) and can handle high-power applications. Taconic CER-10 is specifically designed for high-frequency circuit applications, such as RF and microwave circuits, where signal integrity and performance are critical. It provides stable electrical performance over a wide range of frequencies, making it an ideal choice for high-frequency PCB designs.
What Materials Make of Taconic CER-10?
Taconic CER-10 is a high-performance laminate material that is composed of several layers. The specific composition of Taconic CER-10 laminate includes:
Reinforcement Material: The core of Taconic CER-10 laminate typically consists of woven fiberglass reinforcement. This reinforcement material provides mechanical strength and stability to the laminate.
Resin System: The reinforcement material is impregnated with a high-quality epoxy resin system. The resin acts as a binder, holding the reinforcement layers together and providing electrical insulation.
Ceramic Filler: Taconic CER-10 laminate contains a ceramic filler material, which is dispersed within the resin matrix. The ceramic filler helps to enhance the electrical properties of the laminate, such as its low dielectric constant and low loss tangent.
These materials are carefully selected and combined to create Taconic CER-10, resulting in a laminate with excellent electrical properties, high mechanical strength, and dimensional stability. The specific formulation and manufacturing process used by Taconic ensure consistent performance and reliability of CER-10 laminates.
Technical Parameters and Advantages of Taconic CER-10 laminates?
Taconic CER-10 laminates offer several technical parameters and advantages that make them suitable for high-frequency applications. Here are some key technical parameters and advantages of Taconic CER-10 laminates:
Electrical Properties
Low Dielectric Constant (typically around 3.2): CER-10 laminates exhibit a low dielectric constant, which helps minimize signal loss and impedance variations, especially at high frequencies.
Low Dissipation Factor: The low dissipation factor of CER-10 laminates ensures minimal signal attenuation and distortion, enabling high-quality signal transmission.
Excellent Electrical Stability: CER-10 laminates maintain their electrical properties over a wide range of frequencies and temperatures, ensuring consistent performance.
Mechanical Strength and Dimensional Stability
High Tensile Strength: Taconic CER-10 laminates have high tensile strength, providing mechanical stability and resistance to deformation.
Low Coefficient of Thermal Expansion (CTE): The low CTE of CER-10 laminates helps minimize thermal stress and ensures dimensional stability, especially in applications with varying temperatures.
Processability
Good Dimensional Control: CER-10 laminates offer excellent dimensional control, allowing for precise fabrication and assembly of high-frequency PCBs.
Compatibility with Standard PCB Manufacturing Processes: CER-10 laminates can be easily processed using standard PCB manufacturing techniques, including drilling, routing, and soldering.
Reliability and Quality
Consistent Performance: Taconic CER-10 laminates are manufactured with strict quality control measures, ensuring consistent and reliable performance.
Quality Standards: CER-10 laminates comply with industry standards such as IPC-4101, ensuring their quality and suitability for demanding applications.
RoHS Compliance: CER-10 laminates are free from hazardous substances, making them environmentally friendly and compliant with RoHS regulations.
UL Recognition: Taconic CER-10 laminates have UL recognition, indicating their compliance with safety standards.
ISO 9001 Certification: Taconic’s manufacturing processes for CER-10 laminates are certified to meet the ISO 9001 quality management system standards.
These technical parameters and advantages make Taconic CER-10 laminates a reliable choice for high-frequency PCB applications, offering excellent electrical performance, mechanical strength, and processability.
Taconic CER-10 Laminates Applications
Taconic CER-10 laminates are widely used in various high-frequency applications where excellent electrical performance is required. Some common applications of Taconic CER-10 laminates include:
RF and Microwave Circuits: CER-10 is commonly used in the construction of RF and microwave circuits, such as power amplifiers, filters, couplers, and antennas. Its low dielectric loss and stable electrical properties make it suitable for high-frequency signal transmission.
High-Speed Digital PCBs: With the increasing demand for high-speed digital communication systems, CER-10 laminates are used in high-speed digital PCB designs. They help maintain signal integrity by minimizing signal loss and impedance variations.
Aerospace and Defense Electronics: Taconic CER-10 laminates find applications in the aerospace and defense industries, where high-performance and reliability are crucial. They are used in radar systems, satellite communications, avionics, and other electronic systems.
Automotive Electronics: CER-10 laminates are also used in automotive electronics, especially in applications that require high-frequency signal processing, such as advanced driver-assistance systems (ADAS), infotainment systems, and radar systems.
Test and Measurement Equipment: Taconic CER-10 laminates are utilized in test and measurement equipment, including oscilloscopes, spectrum analyzers, network analyzers, and signal generators. Their excellent electrical properties help ensure accurate and reliable measurements.
These are just a few examples of the applications where Taconic CER-10 laminates are commonly used. The material’s high-performance characteristics make it suitable for various high-frequency electronic applications that demand reliable signal transmission and low loss.
Implications of TG Value on Taconic CER-10 Performance
The Glass Transition Temperature (Tg) is a crucial parameter that significantly impacts the performance and behavior of Taconic CER-10. The Tg value represents the temperature at which the material transitions from a rigid, glassy state to a more flexible, rubbery state. Understanding the implications of Tg on Taconic CER-10 performance is essential for designing and utilizing the material effectively.
Mechanical Stability: The Tg value of Taconic CER-10 directly affects its mechanical stability. Below the Tg temperature, the material is rigid and maintains its structural integrity. Above the Tg temperature, the material becomes more flexible, which can lead to changes in dimensional stability, increased susceptibility to stress, and potential deformation. Therefore, it is crucial to operate Taconic CER-10 below its Tg to ensure optimal mechanical stability in electronic applications.
Thermal Stability: Tg also plays a role in determining the material’s thermal stability. Taconic CER-10’s Tg temperature indicates the point at which the material may start to soften or lose its rigidity when exposed to elevated temperatures. Operating Taconic CER-10 above its Tg can lead to reduced mechanical strength, increased expansion, and potential degradation of its electrical properties. Therefore, it is important to consider the Tg value when designing for high-temperature applications to ensure that Taconic CER-10 remains within its stable operational range.
Processing Considerations: The Tg value of Taconic CER-10 also influences its processing conditions. During manufacturing processes such as lamination, drilling, or soldering, the material may experience temperature variations. Understanding the Tg allows for proper control of the manufacturing process to prevent excessive heating that could affect the material’s properties and performance.
Frequency and Signal Integrity: In high-frequency applications, where signal integrity is critical, Tg becomes particularly relevant. High-frequency electronic signals can induce heat in the substrate, potentially crossing the Tg threshold. Operating Taconic CER-10 below its Tg ensures that the material maintains its electrical properties, dimensional stability, and signal integrity even under high-frequency operation.
By considering the implications of Tg on Taconic CER-10 performance, engineers and designers can make informed decisions regarding temperature limitations, material selection, and processing conditions. Adhering to the recommended operating temperature range and understanding the Tg value enables the optimal utilization of Taconic CER-10 in various electronic applications, ensuring reliability and performance.
How to Choose the Optimal Dk Value for Taconic CER-10?
When selecting the optimal Dielectric Constant (Dk) value for Taconic CER-10, several factors need to be considered to ensure the material’s suitability for the specific application. The Dielectric Constant refers to the material’s ability to store electrical energy in an electric field. Here are some considerations when choosing the Dk value for Taconic CER-10:
Frequency of Operation
The frequency at which the circuit or system will operate is a crucial factor when determining the Dk value. Different frequencies have varying effects on signal propagation and transmission line characteristics. Higher frequencies may require substrates with lower Dk values to minimize signal loss, dispersion, and impedance mismatches. Lower frequencies, on the other hand, may tolerate higher Dk values.
Impedance Control
The Dk value affects the characteristic impedance of transmission lines on the circuit board. For applications requiring precise impedance control, it is essential to choose a Dk value that allows for accurate impedance matching. This consideration is particularly important in high-frequency applications to minimize signal reflections and maintain signal integrity.
Signal Speed and Propagation Delay
The Dk value influences the speed at which signals propagate through the material. Lower Dk values generally result in faster signal speeds, while higher Dk values can lead to slower propagation. Depending on the application requirements, the desired signal speed and propagation delay need to be considered when selecting the Dk value for Taconic CER-10.
Substrate Thickness
The Dk value interacts with the substrate thickness to determine the characteristic impedance of transmission lines. Thicker substrates with higher Dk values result in higher characteristic impedances, while thinner substrates with lower Dk values yield lower characteristic impedances. Understanding the desired characteristic impedance and the required substrate thickness is important for choosing the appropriate Dk value.
Manufacturing Constraints
It is also necessary to consider any manufacturing constraints or limitations related to specific Dk values. Some Dk values may be more readily available or suitable for the manufacturing processes employed, such as lamination, drilling, or etching. Ensuring compatibility with manufacturing capabilities and processes is crucial when selecting the optimal Dk value.
What are the Quality Standards for Taconic CER-10 PCB laminates Material?
Taconic CER-10 PCB material adheres to various quality standards to ensure reliable and consistent performance. Some of the quality standards associated with Taconic CER-10 include:
IPC-4101: This is the standard for base materials used in rigid and multilayer printed boards. Taconic CER-10 meets the requirements specified by IPC-4101, ensuring its suitability for PCB applications.
RoHS Compliance: Taconic CER-10 complies with the Restriction of Hazardous Substances directive, ensuring that it does not contain harmful substances such as lead, mercury, cadmium, and others.
UL Recognition: Taconic CER-10 is recognized by Underwriters Laboratories (UL) for its electrical and mechanical properties, ensuring its safety and reliability.
ISO 9001: Taconic, as a manufacturer, follows the ISO 9001 quality management system, which ensures consistent quality control and continuous improvement in their processes.
These quality standards demonstrate Taconic’s commitment to delivering high-quality and reliable PCB materials like CER-10, meeting industry standards and customer expectations.
Considerations Prior to Purchasing Taconic CER-10
Prior to making a purchase decision regarding the Taconic CER-10, it is prudent to take into consideration the following factors:
TG Value: It is crucial to assess the TG (Glass Transition) value of the Taconic CER-10, as it determines its ability to withstand high temperatures without softening or losing structural integrity in adverse conditions.
Dielectric Constant: The intended deployment environment of the Taconic CER-10 should be carefully considered. Opting for a low Dielectric Constant (Dk) value is particularly advantageous in scenarios involving high-frequency applications, as it ensures minimal signal loss and improved performance.
Thermal Expansion: The thermal expansion characteristics of the Taconic CER-10 are closely related to its TG value. It is imperative to prevent the temperature from exceeding this threshold, as surpassing it may result in undesirable consequences, such as melting or deformation.
Thermal Conductivity: To facilitate efficient heat dissipation, it is recommended to utilize copper or aluminum materials in conjunction with the Taconic CER-10. These metals possess favorable thermal conductivity properties, enabling effective heat transfer and management.
By considering these key aspects, one can make an informed decision when contemplating the acquisition of the Taconic CER-10.
Why Choose JarnisTech Taconic CER-10?
JarnisTech, a distinguished Chinese manufacturer with over 20 years of expertise in producing Taconic CER-10, proudly presents our premium-grade offering that incorporates advanced features. Our Taconic CER-10 surpasses industry standards and delivers heightened flexural strength and the ability to achieve circuit board miniaturization.
As an esteemed manufacturer in this field, JarnisTech has honed its proficiency in producing high-quality Taconic CER-10. We take pride in supplying Taconic CER-10 that exhibits exceptional interlaminar bond, a testament to our commitment to excellence.
By choosing our Taconic CER-10, you can unlock a plethora of benefits for your applications. Our product boasts the following advantages:
Circuit board miniaturization: Our Taconic CER-10 facilitates the creation of compact circuit boards, allowing you to optimize space utilization and enhance overall design efficiency.
Low Z-axis expansion: With minimized expansion in the Z-axis, our Taconic CER-10 ensures dimensional stability, promoting reliable performance and reducing the risk of electrical failures.
Low moisture absorption: By exhibiting low moisture absorption properties, our Taconic CER-10 mitigates the negative effects of moisture on circuit board performance, ensuring consistent functionality in various environmental conditions.
Increased flexural strength: The superior flexural strength of our Taconic CER-10 enables it to withstand bending and mechanical stress, contributing to enhanced durability and reliability of your electronic assemblies.
Enhanced dimensional stability: Our Taconic CER-10 maintains exceptional dimensional stability, which is critical for preserving the precise geometries and alignment of circuit board components, ultimately resulting in optimal electrical performance.
At JarnisTech, we are dedicated to providing you with a premium-quality Taconic CER-10 that meets and exceeds your expectations, empowering you to achieve outstanding results in your electronic applications.
Final Thoughts
Taconic CER-10 is a high-quality material designed for electronic applications. It offers several key features such as increased flexural strength, circuit board miniaturization capabilities, enhanced dimensional stability, low moisture absorption, and low Z-axis expansion. These features make Taconic CER-10 a desirable choice for various electronic design and manufacturing requirements.
The Glass Transition Temperature (Tg) of Taconic CER-10 plays a significant role in its performance. Operating the material below its Tg ensures optimal mechanical and thermal stability, while considering the Tg during manufacturing processes helps maintain the material’s properties.
When choosing the Dielectric Constant (Dk) value for Taconic CER-10, factors such as frequency of operation, impedance control, signal speed, substrate thickness, and manufacturing constraints need to be considered. The Dk value affects signal propagation, impedance matching, and characteristic impedance, and selecting the appropriate Dk value ensures optimal electrical performance.
By understanding the properties, performance implications, and considerations of Taconic CER-10, engineers and designers can make informed decisions to utilize the material effectively in various electronic applications, ensuring reliability, performance, and signal integrity.
