Practical design and evaluation of an 800 W PFC boost converter ...
Tutorial - Boost PFC Converter Control Loop Design
-
Upload
baguspermana7 -
Category
Documents
-
view
242 -
download
1
Transcript of Tutorial - Boost PFC Converter Control Loop Design
Boost PFC Converter Control Loop Design
‐ 1 ‐ Powersim Inc. www.powersimtech.com
SmartCtrl Tutorial
Boost PFC Converter Control Loop Design
Boost PFC Converter Control Loop Design
‐ 2 ‐ Powersim Inc. www.powersimtech.com
SmartCtrl1 is a general‐purpose controller design software specifically for power electronics applications. This tutorial is intended to guide you, step by step, to design the control loops of a PFC (power factor correction) boost converter with the SmartCtrl Software.
The example used in this tutorial is the PFC boost converter circuit that comes with the PSIM example set (the PSIM file is “UC3854_PFC.sch” under the folder “examples\PWM IC”). The PSIM schematic is shown below:
50Hz324Vpk
Rcs0.25
Q
Do
Co450uF
Rpk21.8k
Rpk110k
Rmo3.9k
Rci10k
Rcz6.66432K
CVF
356.753n
RVF
14.2082KC31uF
RVI26.1667K
RVD0.5k
RVAC620k
Rset
10k
CT 1.2n
VVo
Rload592
Lm
1mH
RB1
150kRFF1910k
RFF2
91k
RFF320k
CFF10.1uF
RENA22k
CFF20.47uF
Css 1n
Cpk100pF
1
2
3
4
5
6
7
8 9
10
11
12
13
14
15
16
C1100u
Ccz1.59211n
C21u
15
1
Rs
100
R130k
V Vcc
UC3854
A
Iin
Vin
Lf
300uCf
1u
Vvea
Vv_io
10k
The circuit includes the inner current loop and the outer voltage loop. The current loop regulator parameters are the resistance Rcz and the capacitance Ccz, and the voltage regulator parameters are the resistance RVF and the capacitance CVF, highlighted in the red dotted boxes above.
Let’s assume that these values are unknown. The objective is to design the current/voltage regulators using the SmartCtrl software. The design procedure is described below.
To begin the design process, in SmartCtrl, click on the icon , or from the Data menu, select Predefined topologies ‐> AC/DC converters ‐> PFC Boost converter.
The dialog window will appear as follows.
Voltage regulator
Current regulator
1 SmartCtrl is copyright in 2010 by Carlos III University of Madrid, GSEP Power Electronics Systems Group, Spain
Boost PFC Converter Control Loop Design
‐ 3 ‐ Powersim Inc. www.powersimtech.com
The PFC boost converter is controlled by a double loop control scheme. The inner loop is a current loop, and the outer loop is a voltage loop. Note that the PFC boost converter design must be carried out sequentially. The SmartCtrl program will guide you through this process.
Inner Loop Design
1. Define the converter
Select the plant as Boost (LCS_VMC) PFC for boost PFC converter with the current loop and the voltage loop. Complete the parameters in the corresponding input data window. Note that the input voltage is the peak value. When finished, click OK to continue.
2. Select the current sensor
Select the current sensor among the available types. In this example, select Current sensor, and set the gain to 0.25 based on the circuit (this value is equivalent to the sense resistor value).
Boost PFC Converter Control Loop Design
‐ 4 ‐ Powersim Inc. www.powersimtech.com
3. Select the current regulator
From the inner loop regulator drop‐down menu, select PI as the current regulator type.
4. Select the crossover frequency and the phase margin
SmartCtrl provides a guideline and an easy way of selecting the crossover frequency and the phase margin through the Solution Map. Click on the Set button, and the Solution Map will be shown as below.
In the Solution Map, each point within the white area corresponds to a combination of the crossover frequency and the phase margin that leads to a stable solution. In addition, when a point is selected, the attenuation given by the sensor and the regulator at the switching frequency is provided.
To carry out the selection, left click a point within the white area, or enter the crossover frequency and the phase margin manually.
Boost PFC Converter Control Loop Design
‐ 5 ‐ Powersim Inc. www.powersimtech.com
Once the crossover frequency and the phase margin are selected, the Solution Map will be shown on the right side of the converter input window. If, at any time, one needs to change the crossover frequency or the phase margin, click on the white area of the Solution Map, as shown in the figure below.
Once the inner loop design is completed, one can move on to the outer loop design.
Boost PFC Converter Control Loop Design
‐ 6 ‐ Powersim Inc. www.powersimtech.com
Outer Loop Design
The procedure of designing the outer loop is similar to that of the inner loop design. It includes the following:
1. Select the voltage sensor
When using a voltage divider, one must enter the reference voltage, and the program will automatically calculate the sensor gain. In this example, the reference voltage is 7.5V. The sensor input data window is shown below.
Reference voltage
Then press on “Calculate Vref/Vo from Vref” button to set the attenuation of the voltage divider.
Boost PFC Converter Control Loop Design
‐ 7 ‐ Powersim Inc. www.powersimtech.com
2. Select the outer loop regulator
In this example, select PI as the regulator type, and enter the regulator parameters as below.
3. Determine the crossover frequency and the phase margin
Similar to the inner loop design, the crossover frequency and the phase margin of the outer loop must be selected. A Solution Map is also provided to help select a stable solution. Press the Solution map (outer loop) button and the solution map will appear.
Boost PFC Converter Control Loop Design
‐ 8 ‐ Powersim Inc. www.powersimtech.com
Then select a point by clicking within the white area, and click OK to continue.
Once the crossover frequency and the phase margin are selected, the Solution Map will appear on the right side of the converter input window. If, at any time, these two parameters need to be changed, click in the white area of the Solution Map, as shown in the figure below.
Boost PFC Converter Control Loop Design
‐ 9 ‐ Powersim Inc. www.powersimtech.com
Accept the selected design by clicking on OK. The program will automatically show the control system performance by means of the Bode plots, the Nyquist plot, phase margin, etc.
SmartCtrl provides the regulator component values needed to implement the regulators, as well as the voltage divider resistors. Since there are two control loops, one must select which one to display.
Display inner loop
Display outer loop
Display outer loopsolutions map
Display inner loopsolutions map
At this point, the control loop design of the converter will be completed. We will validate the design by means of time‐domain simulation.
Boost PFC Converter Control Loop Design
‐ 10 ‐ Powersim Inc. www.powersimtech.com
Design Verification through Simulation
In order to validate the design from SmartCtrl, time‐domain simulation is carried out in PSIM.
We will compare the performance of the converter with two different designs.
Design #1 Design #2
Inner loop: fcross=3 kHz Phase Margin=45º
Outer loop: fcross=30 Hz
Inner loop: fcross=15 kHz Phase Margin=45º
Outer loop: fcross=30 Hz
Output voltage
Input voltage
Input current*50
Output voltage
Input voltage
Input current*50
It can be observed that Design #2 shows a much less waveform distortion that Design #1, and that the waveform distortion can be greatly reduced by increasing the crossover frequency of the inner loop.
This example illustrates that SmartCtrl in combination with PSIM provide a fast and powerful platform for the design and validation of converter control for power factor correction applications.