High-power LED package features High-power LED package has been a research hotspot in recent years due to its complicated structure and process, and directly affects the performance and life of LED. Especially, high-power white LED package is a hot spot in research. The choice of LED packaging methods, materials, structures, and processes is primarily determined by factors such as chip structure, optoelectronic/mechanical characteristics, specific applications, and cost. After more than 40 years of development, LED packaging has experienced the development stages of stent (LampLED), SMD (SMDLED), and power LED (PowerLED). With the increase of chip power, especially the development of solid-state lighting technology, new and higher requirements are put forward for the optical, thermal, electrical and mechanical structures of LED packages. In order to effectively improve the light extraction efficiency, a new technical idea must be adopted for the package design. The role of phosphors in LED packaging is to combine light and color to form white light. Its characteristics mainly include particle size, shape, luminous efficiency, conversion efficiency, stability (heat and chemistry), etc., among which luminous efficiency and conversion efficiency are key. Studies have shown that as the temperature rises, the quantum efficiency of the phosphor decreases, the light emission decreases, and the radiation wavelength also changes, which causes the color temperature and chromaticity of the white LED to change, and the higher temperature accelerates the aging of the phosphor. The reason is that the phosphor coating is prepared by epoxy or silica gel and phosphor, and the heat dissipation performance is poor. When subjected to ultraviolet light or ultraviolet light, temperature quenching and aging are liable to occur, and the luminous efficiency is lowered. In addition, the thermal stability of potting and phosphors at high temperatures is also problematic. Since the common phosphor size is above 17um, the refractive index is greater than or equal to 1.85, and the refractive index of silica gel is generally around 1.5. Due to the mismatch in refractive index between the two, and the phosphor particle size is much larger than the light scattering limit (30 nm), light scattering exists on the surface of the phosphor particles, which reduces the light extraction efficiency. By incorporating nano-phosphor in silica gel, the refractive index can be increased to above 1.8, the light scattering can be reduced, the LED light-emitting efficiency can be improved (10%-20%), and the light color quality can be effectively improved. Or use matching light diffusion powder to improve LED light extraction efficiency. For example, Hongdae's 432 is generally used with a particle size of 8-9 um and a fine particle size of 4 um. Therefore, F is a fine particle phosphor. Mainly used in high-power LED package (silica gel or epoxy resin) phosphor coating, the general addition amount is 10-20%. Applications: Taking white LED as an example, the refractive index of the chip is about 2-4, such as GaN (n=2.5) and GaP (n=3.45), which are much higher than the refractive index of epoxy resin or silicone resin encapsulant (n=1.40~1.53). If the difference in refractive index is too large, total reflection occurs, and the light is reflected back inside the chip and cannot be effectively exported. Therefore, increasing the refractive index of the package material can reduce the occurrence of total reflection. Taking the white LED component of the blue chip/**YAG phosphor as an example, the blue LED chip has a refractive index of 2.5, and when the refractive index of the packaging material is raised from 1.5 to 1.7, the light extraction efficiency is improved by nearly 30%; A method in which the refractive index of the encapsulating material reduces the refractive index difference between the chip and the encapsulating material to achieve an improved light-emitting efficiency is feasible. In general, in order to improve the light-emitting efficiency and reliability of the LED, the encapsulant layer has a tendency to be gradually replaced by a phosphor of a high-refractive-index ultrafine particle, and by incorporating the fine-particle phosphor, the phosphor is not only improved. Uniformity and improved packaging efficiency. In addition, reducing the number of optical interfaces in the direction in which the LEDs are emitted is also an effective means of improving the light extraction efficiency. A vector inverter, also known as a variable frequency drive (VFD) or adjustable speed drive (ASD), is an advanced power electronic device used to convert direct current (DC) power into alternating current (AC) power. It operates by employing complex control algorithms and sophisticated power electronics to regulate the frequency, voltage, and phase of the AC output waveform.
Power electronics, DC to AC conversion, Frequency control, Voltage regulation, Phase synchronization WuXi Spread Electrical Co.,LTD , https://www.vfdspread.com
Vector inverters are widely used in various industries and applications due to their ability to provide precise control over the speed and torque of AC motors. By adjusting the frequency and voltage of the AC output, vector inverters can effectively regulate the motor's rotational speed, enabling smooth acceleration, deceleration, and precise positioning. This makes them essential in applications where precise control over motor speed and torque is required, such as industrial machinery, robotics, HVAC systems, and electric vehicles.
One of the key features of vector inverters is their ability to provide vector control, also known as field-oriented control (FOC). Vector control allows for independent control of the motor's magnetizing flux and torque, resulting in improved motor performance and efficiency. By accurately adjusting the motor's magnetic field and torque components, vector inverters can minimize energy losses, reduce motor heating, and enhance overall system efficiency.
In addition to motor control, vector inverters offer a range of advanced features and protection mechanisms. They typically include built-in functions for fault detection, overcurrent protection, overvoltage protection, and thermal protection, ensuring safe and reliable operation of the system. Furthermore, many vector inverters support communication protocols such as Modbus, Ethernet, and Profibus, facilitating integration with supervisory control systems and enabling remote monitoring and control.
Vector inverters are also extensively used in renewable energy systems, such as wind turbines and solar photovoltaic (PV) systems. They play a crucial role in converting the variable DC power generated by renewable sources into stable and grid-compatible AC power. By efficiently tracking and regulating the power output, vector inverters enable optimal power harvesting from renewable sources while ensuring grid stability and compliance with grid codes.
Overall, vector inverters are versatile devices that provide precise and efficient control over AC motors, making them indispensable in a wide range of industrial, commercial, and residential applications. With their advanced features, protective mechanisms, and compatibility with renewable energy systems, vector inverters contribute to enhanced energy efficiency, improved system performance, and sustainable energy utilization.