Insulation material performance index
(1) Compressive strength: In the electric field, the insulating material breaks down when the electric field strength increases to a certain limit. The electric field strength of this insulation breakdown is called the dielectric strength (also called dielectric strength or dielectric strength), and is usually expressed as a voltage KV value that a 1 mm thick insulating material can withstand.
(2) Tensile strength: The tensile force per unit sectional area of ​​the insulating material can withstand, for example, the glass can withstand 140 kilograms per square centimeter of cross-sectional area.
(3) Density: The mass per cubic meter of insulation material, for example 2 grams per cubic meter of sulfur.
(4) Coefficient of expansion: The extent to which the insulator increases in volume after it is heated.
3. Heat-resistant grades of insulating materials (1) Class Y insulating materials: natural textiles such as wood, cotton, and fibers, textiles based on acetate and polyamide, and materials that are easily decomposed and have a low melting point.
Extreme operating temperature: 90 degrees.
(2) Class A insulating materials: Grade Y materials impregnated with mineral oils and impregnated with oil or oleoresin composites, insulation of enameled wire, varnished cloth, lacquer, and oil paint. Asphalt paint and so on.
Limit working temperature: 105 degrees.
(3) Class E insulating materials: Polyester film and A-grade material composite, glass cloth, oil-based resin paint, polyvinyl acetal high-strength wire, vinyl acetate heat-resistant wire.
Extreme operating temperature: 120 degrees.
(4) Class B insulation material: polyester film, impregnated mica, glass fiber, asbestos, etc., with appropriate resin, polyester paint, polyester enameled wire.
Extreme operating temperature: 130 degrees.
(5) Class F insulation materials: mica products reinforced with organic fiber materials, glass wool and asbestos, glass wool cloth, laminated products based on glass wool cloth and asbestos fiber reinforced with inorganic materials as reinforcement and stone belts Mica powder products chemical thermal stability better polyester or alkyd materials, composite silicone organic polyester paint.
Limit working temperature: 155 degrees.
(6) Class H insulating materials: mica products without reinforcement or reinforcement with inorganic materials, thickened F-class materials, composite mica, silicone mica products, silicon organic paint silicone organic rubber polyimide composite glass cloth, Composite film, polyimide paint and so on.
Limit working temperature: 180 degrees.
(7) Class C insulating materials: Inorganic materials that do not use any organic binder and agent grade infusions, such as quartz, asbestos, mica, glass, and electric porcelain materials.
Limit working temperature: 180 degrees or more.
A hybrid inverter is an inverter that combines the functions of an inverter and a charge controller. Its main function is to simultaneously process the direct current generated by solar panels and the electric energy of the battery energy storage system in a photovoltaic power generation system. It converts the direct current generated by the solar panels into alternating current for power and stores the excess power in the battery so that it can continue to supply power when needed.
Main effect:
Solar power generation: Hybrid inverters convert the direct current generated by solar panels into alternating current for home, commercial, or industrial electricity needs.
Battery energy storage: The hybrid inverter is equipped with a battery energy storage system that can store excess solar power. When the Solar Panel cannot generate enough electricity, the electricity stored in the battery can continue to supply electricity to achieve a continuous power supply.
Grid-connected function: Some hybrid inverters also have grid-connected functions, that is, the excess electric energy is integrated into the grid for use by other users. This allows them to interact with the grid, be self-sufficient, and export electricity to the grid.
Differences from other inverters:
Charging control function: The hybrid inverter combines the functions of an inverter and a charge controller, and can simultaneously process the DC power of the solar panel and the DC power of the battery energy storage system, realizing the hybrid application of solar power generation and battery energy storage.
Standalone operation: Unlike microinverters, hybrid inverters can operate independently and do not require an inverter for each solar panel, so it may be more economical and convenient when the system is larger.
Applicable scenarios: Hybrid inverters are widely used in home, commercial, and industrial photovoltaic power generation systems, especially in hybrid application scenarios that require photovoltaic power generation and battery energy storage.
In general, the main function of the hybrid inverter is to convert the direct current of the solar panel and the battery energy storage system into alternating current, so as to realize the hybrid application of photovoltaic power generation and battery energy storage. Compared with other inverters, it has higher flexibility and reliability in energy management and power supply stability.
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