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Experiment-5 Power Electronics

The document outlines an experiment focused on studying a Boost converter, including objectives related to PWM generation and performance analysis with varying components. It details the necessary equipment, circuit diagram, and step-by-step procedures for both PWM circuit and Boost converter studies, along with observation tables for data recording. Additionally, it provides specifications for the ST2727 Boost converter and guidelines for safe operation and output limits.

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kitagawamarin182
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41 views4 pages

Experiment-5 Power Electronics

The document outlines an experiment focused on studying a Boost converter, including objectives related to PWM generation and performance analysis with varying components. It details the necessary equipment, circuit diagram, and step-by-step procedures for both PWM circuit and Boost converter studies, along with observation tables for data recording. Additionally, it provides specifications for the ST2727 Boost converter and guidelines for safe operation and output limits.

Uploaded by

kitagawamarin182
Copyright
© © All Rights Reserved
We take content rights seriously. If you suspect this is your content, claim it here.
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Download as PDF, TXT or read online on Scribd
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EXPERIMENT No.

STUDY OF BOOST CONVERTER


Name ID No.

Sec.No Batch No. Marks obtained

Date Instructor’s signature

OBJECTIVES
a. To Study the PWM generation Circuit for Boost converter.
b. Study the performance of the Boost converter for different values of L,C and load

EQUIPMENTS NEEDED
1. Oscilloscope
2. Digital Multimeter
3. BNC to Test Probe
4. Techbook Scientech 2727 and power supply.
5. Patch Cords & Operating manual

CIRCUIT DIAGRAM:

Figure 5.1 Power circuit for Boost converter

PROCEDURE FOR STUDYING THE PWM CIRCUIT.


Make sure that there is no connection on the board initially.
1. Connect the Power supply (SMPS) to Techbook Scientech 2727.
2. Switch on the instrument.

EEE/INSRT F342 Power Electronics Page 18


3. Observe the output of PWM Generation block at TP1 with respect to GND on oscilloscope.
4. Observe the output of optical isolation block at TP2 with respect to ISO_GND on oscilloscope.
5. Observe the Gate pulse at TP3 with respect Vs.
6. Vary the frequency control potentiometer to observe frequency variation on the oscilloscope.
7. Vary the Duty Cycle control potentiometer to observe the duty cycle variation on the
oscilloscope.
8. Switch OFF the Power supply Unit. Remove the test probes from ST 2729.

OBSERVATION TABLE 5.1:


Minimum Maximum Minimum Pulse Maximum Pulse
Frequency Frequency Width Width
(Hz) (Hz) (%) (%)

PROCEDURE FOR STUDYING THE BOOST CONVERTER


Make sure that there is no connection on the board initially.
1. Switch ON the Power supply unit.
2. Set the chopping frequency at 20 KHz by the frequency potentiometer.
3. Set the PWM duty cycle at minimum by varying Duty cycle control potentiometer.
4. Switch OFF the Power supply unit.
5. Connect one end of inductor L1 to the diode D1 & the other end of inductor L1 to positive terminal of
capacitor C1.
6. Connect the one end of the RL1 to the one end of the load terminal & other terminal of the RL1 to
the other end of the load.
7. Connect the GATE pulse to the gate of the T1 (IGBT).
8. Connect +24V and ISO_GND to the boost configuration.
9. Switch on the instrument.
10.Vary the PWM control potentiometer at different pulse width. Observe the variable DC voltage acrossthe
load.
11. Verify the output DC voltage with the theoretical value.
12. Connect the multimeter in DC mode and vary the PWM control potentiometer and observe the output
voltage across the load, switch and diode.
13. Connect the oscilloscope and vary the PWM control potentiometer & observe the waveforms of
inductor current, diode current, output capacitor ripple voltage, and capacitor current. (For output ripple
voltage, measure Vo in ac coupling.)

EEE/INSRT F342 Power Electronics Page 19


14. Switch ‘Off’ the power supply.
15. Repeat the experiment for different values of L, C and load.
16. Disconnect all the connections from the board.

OBSERVATION TABLE 5.2


Frequency f = 20 kHz
Input Voltage = 𝑉i𝑛
Output Voltage = 𝑉0
Duty ratio = 𝐷
1
𝑉0 = 𝑉i𝑛
1−𝐷

Measured Theoretica Measured Measured


Inductor
S. Capacitor Output l Output voltage across voltage
value PWM (%)
No. (µF) Voltage Voltage (V) the switch across the
(µH)
(V) (V) diode (V)

1 L1 C1 20%

2 L1 C1 30%

3 L1+L2 C1 20%

4 L1+L2 C1 30%

GRAPHS
1. Draw the graphs of PWM output, inductor current, diode current and capacitor current for duty
ratio of 0.3 for the values of L1+L2 and C1 for Boost converter.
2. Draw the graphs of PWM output, inductor current, diode current and capacitor current for duty ratio of 0.2
for the values of L1+L2 and C1 for Boost converter.

EEE/INSRT F342 Power Electronics Page 20


Specification for the ST2727 Boost converter

SMPS : +/- 12V@ 500mA, +5V@250mA SMPS :

+/- 12V@ 500mA, +5V@250mA SMPS : +/-

15V@1A

SMPS : +24 V@1A for DC rail

Input DC Voltage : 24V/1A

PWM Frequency Variation : 1 KHz to 22 KHz

Duty Cycle Variation : 10% to 45%

Power Isolation Section : Single channel, 10x

Power device : IGBT TOSHIBA 20JT101

Diode : UF4007

MOSFET/ IGBT Driver : MC33153

Rsense : 0.1Ω

Turn off Snubber : 100E 1W & 0.1µF 250V

Dimensions (mm) : W 326 x D 252 x H 52

Power Supply : 110V - 260V AC, 50/60Hz

Weight : 1.5Kg (approximately)

Operating Conditions : 0-400 C, 85% RH

L1 L2 L3 C1 C2 C3 RL1 RL2

1.5mH 404uH User 1000uF/63V 470uF/63V 220uF/63V 75Ω/ 25W 75Ω/ 25W

Please use external load for observing output power more than 15W. The maximum output power should not
exceed 20W.

EEE/INSRT F342 Power Electronics Page 21

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