Korkeataajuiset invertterisähkölaitteet ovat eräänlaisia kytkinlaitteita, joita käytetään teollisuudessa. Mikä on suurtaajuusmuuttajien toimintaperiaate? Tätä laitetta ohjataan ohjelmalogiikalla. High frequency inverter can be used in the telecommunications industry and is a switching device in computer rooms. This kind of power supply can be used in the solar energy industry and power generation industry. It is a switching power supply device that uses data line output and is very safe. This article mainly introduces the working principle of high-frequency inverter and the difference between high-frequency inverter and low-frequency inverter. Follow the editor to learn more.
A high-frequency inverter is a DC to AC transformer. It is actually a voltage inversion process with a converter. The working principle of the high-frequency inverter is that the converter converts the AC voltage of the power grid into a stable 12V DC output, while the inverter converts the 12V DC voltage output by the Adapter into high-frequency, high-voltage AC power; both parts are equally The widely used pulse width modulation (PWM) technology is adopted. Its core part is a PWM integrated controller, the Adapter uses UC3842, and the inverter uses TL5001 chip. The operating voltage range of TL5001 is 3.6~40V. It is equipped with an error amplifier, a regulator, an oscillator, a PWM generator with dead zone control, a low-voltage protection circuit and a short-circuit protection circuit.
1. Input connection part: Syöttöosassa on 3 signaaleja, 12V DC-tulo VIN, käyttöjännite ENB ja paneelivirran ohjaussignaali DIM. VIN:n antaa sovitin, ja ENB-jännitteen antaa emolevyn MCU. Its value is 0 tai 3V. Kun ENB=0, invertteri ei toimi, ja kun ENB=3V, the inverter is in normal working condition and the DIM voltage is Provided by the mainboard, its variation range is between 0~5V. Different DIM values are fed back to the feedback terminal of the PWM controller. Invertterin kuormaan antama virta on myös erilainen. Mitä pienempi DIM-arvo, the smaller the current output by the inverter. Isompi.
2. Voltage starting circuit: When ENB is at a high level, it outputs high voltage to light up the Panel's backlight tube.
3. PWM ohjain: Siinä on seuraavat toiminnot: sisäinen vertailujännite, virhevahvistin, oskillaattori ja PWM, overvoltage protection, undervoltage protection, short circuit protection, and output transistor.
4. DC muunnos: A voltage conversion circuit is composed of a MOS switching tube and an energy storage inductor. The input pulse is amplified by a push-pull amplifier and drives the MOS tube to perform switching actions, so that the DC voltage charges and discharges the inductor, so that the other end of the inductor can Get AC voltage.
5. LC-värähtely ja lähtöpiiri: ensure the 1600V voltage required to start the lamp, and reduce the voltage to 800V after the lamp is started.
6. Lähtöjännitteen palaute: Kun kuorma toimii, the sampling voltage is fed back to stabilize the inverter voltage output.