DC/DC conversion circuit diagram without isolation
Source: InternetPublisher:elleny Keywords: conversion circuit circuit diagram DC Updated: 2020/05/05
For a converter circuit that does not need to be isolated from the input and output voltages but only uses a working switch and L, D, and C, the most basic forms are as follows: Buck Converter (Buck Converter ), Boost Converter Converter (BoostConverter) and buck/boost converter (Buck-Boost Converter). The circuit principle is shown in the figure.
ck="window.open(this.src)" alt="Click to see larger image"/>
1. Buck converter
As shown in Figure (a) 9, in order to reduce the output ripple, an inductor L and a capacitor C are connected to the output end. VD in the figure is the freewheeling diode. The average value of the buck converter output voltage Vo is always less than the input voltage Vin. Whether the current iL in the inductor is continuous depends on the switching frequency, the parameter values of the filter inductor L and the capacitor C.
When the operating frequency of the circuit is high, if the inductance value of the inductor and the capacitance of the capacitor are large enough and they are ideal components, the output voltage can be considered to be constant after the circuit enters a steady state. When the transistor VT is turned on, the current in the inductor rises linearly; when the transistor VT is turned off, the current in the inductor cannot change suddenly, and the induced electromotive force on it causes the diode to turn on. In the steady state, the inductor filter maintains the DC component and eliminates the harmonic components, so the average output current is Io=Vo/RL;, where RL is the resistance of the load resistor.
2. Boost converter
Figure (b) shows a boost converter, which consists of a power transistor VT, an energy storage inductor L, a diode VD and a filter capacitor C. When the transistor VT is turned on, the power supply stores energy in the inductor, the inductor current increases, the polarity of the induced electromotive force is left positive and right negative, and the load capacitor C supplies power. When VT stops, the inductor current decreases, the polarity of the induced electromotive force is negative on the left and positive on the right. The inductor releases energy, supplies power to the load through the diode VD together with the input voltage, and charges the capacitor C at the same time. This converts low-voltage direct current into high-voltage direct current.
3. Buck/boost converter
Figure (c) shows a buck/boost converter. The average value of the output voltage Vo is greater than or less than the input voltage Vin, and their polarities are opposite.
- TPS274C65 helps reduce downtime and increase productivity in 24 VDC power distribution plants
- 220V Remote Load Monitor
- Driving circuit of switching power supply field effect tube
- What kind of circuit is a voltage regulator circuit?
- Basic circuit description of adjustable voltage regulator LM317
- Recommended circuits for different power on times of LM4911
- Miniature polarity reversal power supply using MAX1721
- Homemade Electric Bike Fast Charger
- Circuit diagram explanation: simple switching power supply circuit diagram
- Detailed explanation of mobile phone charger circuit diagram
- MC3406A step-down DC-DC integrated converter
- Radio remote control doorbell circuit b
- Mechanical electric shock switch value conversion circuit c
- AD2S80A, AD2S81A, AD2S82A RDC monolithic integrated circuits
- DC/DC converter regulator circuit 01
- Rongsheng DCX-63A dual temperature electronic disinfection cabinet circuit diagram
- Simple positive polarity DC, DC converter circuit diagram
- Positive polarity DC, DC converter circuit diagram
- DC and DC converter circuit diagram with magnetic amplifier
- 3V-5V DC DC conversion circuit
京公网安备 11010802033920号