![REFERENCES:
[1] W. H. Li and X. N. He, “Review of non-isolated high
step-up DC/DC converters in photovoltaic grid-
connected applications,” IEEE Trans. Ind. Electron.,
vol. 58, no. 4, pp. 1239–1250, Apr. 2011.
[2] C. T. Pan and C. M. Lai, “A high-efficiency high
step-up converter with low switch voltage stress for
fuel-cell system applications,” IEEE Trans. Ind.
Electron., vol. 57, no. 6,
[3] T. F. Wu and Y. K. Chen, “Modeling PWM DC–DC
converters out of basic converter units,” IEEE Trans.
Power](https://image.slidesharecdn.com/transformerlessbuckboostconverter-170510032547/85/Transformerless-buckboost-converter-by-SEPURI-21-320.jpg)
Transformerless buckboost converter by SEPURI
- 1. GATES INSTITUTE OF TECHNOLOGY ( Department of Electrical and Electronics Engineering) A NEW TRANSFORMERLESS BUCK-BOOST CONVERTER WITH POSITIVE OUTPUT VOLTAGE Submitted by SEPURI MAHESH SEPURI YASASWINI Under The Guidance of Mr.N.GANGADHAR M.Tech Associate professor EEE.
- 2. ABSTRACT: A new transformer less buck-boost converter with simple structure is proposed in this study . Compared with the traditional buck-boost converter, the proposed buck-boost converter , voltage gain is squared times of the former’s and its output voltage polarity is positive. In the continuous conduction mode two inductors are magnetised and two capacitors are discharged during the switch on period, While two inductors are demagnetised and two capacitors are charged during the switch of period.
- 3. OBJECTIVE: •In this project a buck-boost converter is used in order to replace the transfomer. •A buck-boost converter gives higher efficiency and it is simple in structure but it has some limited voltage gain with positive output voltage.Due to this reason here we are using a buck-boost converter.
- 4. INTRODUCTION: As is well known, switching-mode power supply is the core of modern power conversion technology which is widely used in electric power, communication system, house hold appliances, and many other fields. As the basis of switching mode power supply, converter topologies attract a deal of attention and many converter and many converter topologies have been proposed. The operating principles the steady state analyses , and the small signal model for the proposed buck-boost converter operating in continuous conduction mode are presented in detail.
- 5. EXISTING SYSTEM: Luo converter can obtain high voltage gain by employing the voltage lift technique, but the topological complexity, cost, volume and losses increases the same time . Interleaved converters can achieve high step up or step down conversion ratio with low voltage stress, while their operating mode ,converter structure and control strategy are complicated.
- 6. •In this proposed system, An additional switched network is inserted into the traditional buck-boost converter a new transformerless buck-boost converter is proposed. •The main part of the proposed buck-boost converter is that its voltage gain is quadratic of the traditional buck-boost converter so that it can operate in a wide range of output voltage, that is, the proposed buck-boost converter can achieve high or low voltage gain without extreme duty cycle. •Moreover, the output voltage of this new transformerless buck-boost converter is common-ground with the input voltage, and its polarity is positive. PROPOSED SYSTEM:
- 7. CIRCUIT DIAGRAM: Fig: Proposed transformer less buck–boost converter
- 8. WORKING OF BUCK-BOOST CONVERTER According to the state of the power switches and diodes, some typical time-domain waveforms for this new transformer less buck–boost converter operating in CCM are displayed in and the possible operation states for the proposed buck–boost converter are shown in fig. For it denotes that the power switches S1 and S2 are turned on, whereas the diodes D1 and D0 do not conduct. Consequently, both the inductor L1 and the inductor L2 are magnetized, and both the charge pump capacitor C1 and the output capacitor C0 are discharged. It describes that the power switches S1 and S2 are turned off while the diodes D1 and D0 conduct for its forward biased voltage. Hence, both the inductor L1 and the inductor L2 are demagnetized, and both the charge pump capacitor C1 and the output capacitor C0 are charged. Here, in order to simplify the circuit analyses and deduction, we assumed that the converter operates in steady state, all components are ideal, and all capacitors are large enough to keep the voltage across them const
- 9. STEP-DOWN MODE: Fig. Simulink model of step down mode
- 10. STEP-DOWN OUTPUT: Fig capacitor (C1) and load resistances voltage wave forms of step down mode (voltage on Y-axis, time on X-axis)
- 11. STEP-DOWN OUTPUT: Fig Voltage output at load in step down mode (voltage on Y axis ,time on X axis) )
- 12. STEP-DOWN OUTPUT: Fig.6.2.4: voltage across the Capacitor (voltage on Y axis, time on X axis)
- 13. STEP-DOWN OUTPUT: Fig Current 𝐼𝐿1across inductor 1(current on Y axis, time on X axis)
- 14. STEP-DOWN OUTPUT: Fig. Current 𝐼𝐿2across inductor 2(current on Y axis, time on X axis)
- 15. STEP-UP MODE: Fig Simulink model of step up mode
- 16. STEP-UP OUTPUT: • Fig capacitor (C1) and load resistances voltage waveform of step up mode (voltage on Y axis, time on X axis)
- 17. STEP-UP OUTPUT: Fig: 6.2.9 Current 𝐼𝐿1 across the inductor 1(current on Y axis, time on X axis)
- 18. Portable electronic devices Car electronic devices Communication system Industrial device House hold appliances APPLICATIONS:
- 20. CONCLUSION: This Project has proposed a new transformer less buck– boost converter as a fourth-order circuit, which realizes the optimization between the topology construction and the voltage gain to overcome the drawbacks of the traditional buck–boost converter. The operating principles, steady- state analyses, small signal modeling, and comparisons with other converters are presented. from the MATLAB simulations, it is proved that the new transformer less buck–boost converter possesses the merits such as high step-up/step-down voltage gain, positive output voltage. Hence, the proposed buck–boost converter is suitable for the industrial applications requiring high step-up or step- down voltage gain.
- 21. REFERENCES: [1] W. H. Li and X. N. He, “Review of non-isolated high step-up DC/DC converters in photovoltaic grid- connected applications,” IEEE Trans. Ind. Electron., vol. 58, no. 4, pp. 1239–1250, Apr. 2011. [2] C. T. Pan and C. M. Lai, “A high-efficiency high step-up converter with low switch voltage stress for fuel-cell system applications,” IEEE Trans. Ind. Electron., vol. 57, no. 6, [3] T. F. Wu and Y. K. Chen, “Modeling PWM DC–DC converters out of basic converter units,” IEEE Trans. Power
Editor's Notes
- #19: APPICATIONS