Industrial Type Capacitors
Industrial-type capacitor is a specific type of capacitor designed for use in industrial applications
that require high power, high voltage, and high current handling capabilities.
The components are subjected to heat treatment. This process can relieve stresses in the materials, improving durability, and ensuring the stability of the capacitor's electrical properties.
Testing the core, especially after energizing, is crucial. This step ensures the core to meet the necessary electrical specifications and is free from defects.
Finally, the capacitors that pass all tests and inspections will be stored, which are ready for distribution or further processing.
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READ MORESurge snubber capacitors (also known as surge suppression capacitors or transient voltage suppression capacitors) are primarily used in circuits to protect equipment from overvoltage damage caused by lightning, power switching, or other transient events. When selecting materials for surge buffer capacitors, manufacturers consider a variety of factors, including the capacitor's electrical performance, physical characteristics, cost, and long-term stability.
material selection
Metal Oxide Varistors (MOVs): MOVs are a common material used in surge snubber capacitors. They are composed of zinc oxide (ZnO) and other metal oxides (such as cobalt, manganese, nickel, etc.). When an applied voltage exceeds the threshold of MOVs, they undergo a transition from a high-resistance state to a low-resistance state, allowing large currents to flow and suppressing voltage rise.
Polymer Matrix Composite Materials: In recent years, polymer matrix composite materials have also been used in surge buffer capacitors. These materials combine the high insulating properties of polymers with the conductivity of conductive particles such as carbon black, metal oxides, etc. When the voltage exceeds a certain threshold, the polymer between the conductive particles breaks down to form a conductive channel, thereby suppressing the voltage rise.
Ceramic Materials: Certain ceramic materials are also used in surge buffer capacitors. They have excellent thermal stability and electrical properties, but may cost more.
advantage
MOVs: MOVs have good nonlinear voltage-current characteristics and can provide effective surge protection over a wide voltage range. In addition, they have high energy absorption capacity and good thermal stability.
Polymer-based composite materials: These materials have lower capacitance and better high-frequency performance, making them suitable for high-speed data transmission and radio frequency applications. In addition, they offer high reliability and long service life.
Ceramic materials: Ceramic materials have excellent electrical properties and thermal stability, and are suitable for high temperature and high humidity environments.
limitation
MOVs: While MOVs have good surge protection properties, they can be affected by temperature, humidity, and mechanical stress. Additionally, their performance may gradually degrade after experiencing multiple surge events.
Polymer Matrix Composites: The properties of these materials can be affected by temperature and humidity. Their electrical properties may change in high temperature or high humidity environments.
Ceramic Materials: Ceramic materials are generally brittle and prone to cracking under mechanical stress. Additionally, their cost can be high, limiting their use in some low-cost applications.
In the early stages of the manufacturing process, detailed circuit design and component selection are required based on the specific application environment and needs of the capacitor. This includes selecting the appropriate capacitor type, dielectric, internal electrode materials, etc.
Pay particular attention to the fact that the capacitors should be able to withstand expected surge voltages and currents, as well as have good thermal stability and durability.
Material selection and control:
Choosing high-quality, stable-performance raw materials is the basis for ensuring the stability and reliability of capacitors.
The factory should establish a strict material inspection system and conduct strict quality control and screening of incoming materials.
Manufacturing process control:
During the manufacturing process, the process parameters of each production link, such as temperature, pressure, time, etc., should be strictly controlled to ensure the consistency and stability of the capacitor.
Especially for the key manufacturing steps of capacitors, such as dielectric coating, electrode manufacturing and assembly, advanced process technology and equipment should be used to ensure manufacturing accuracy and product quality.
Quality inspection and evaluation:
During the manufacturing process, a strict quality inspection system should be established to conduct multiple quality inspections on capacitors, such as appearance inspection, electrical performance testing, environmental adaptability testing, etc.
Capacitors that fail the test should be repaired or scrapped in time to ensure the quality of the factory capacitors.
Environmental suitability test:
Since capacitors may need to work under various complex environmental conditions, environmental adaptability tests should be conducted, such as temperature shock, damp heat, salt spray and other tests.