GRID INTERCONNECTION OF HIGH STEP UP DC TO AC CONVERTER WITH RENEWABLE SOURCE INTEGRATION AND RESONANT SWITCH CAPACITOR
Abstract
In this paper a new high step up DC to AC converter is introduced with controlled pulse width modulation technology. The power output of the 3 phase AC is connected to the grid using the LC filter. The converter is connected to a low-voltage -renewable power source such as PVA or battery. Low voltage increases in high voltage through the proposed converter with an inductor integrated with a resonant switched capacitor. Due to the synchronization of the Sync unit synchronous boost unit with multiple integrated inductor-SC units the structure can be easily expanded to gain ultrahigh voltage. Electronic power switch works with soft fluctuations with reduced voltage pressure which increases the reliability of the converter. MOSFET power switches are used to control the output voltage with a frequency switch frequency of 100 kHz. This high frequency switch reduces the DC power output bursting and reduces the harmonics on the AC power side. The converted AC power output is synchronized to the grid by the control loop control using an independent reference method. The complete model was developed in the MATLAB Simulink environment with discrete circuit analysis. Graphs are sorted by time and defined using the GUI environment
References
[2] Y. Ye, K. W. E. Cheng, J. Liu, and K. Ding, "Modified multilevel capacitor step in power measurement," IEEE Trans. Ind. Electron., IV. 61, no. 12, p. 6672-6680, December. 2014.
[3] H. Liu, H. Hu H. Wu Y. Xing, and I Batarseh, "The full view of the fastest students of change," IEEE J. Emerge. Sel. Texts Power Electron. Vol. 4, no. 2, p. 689-704, Jun. 2016.
[4] K. K. Law, K. W. E. Cheng, no-Y. P. Benny Yeung, "Design and analysis of transformational tools using step-by-step flexibility," IEEE Trans. Scenes Syst. Mina, Reg. Papers, vol. 52, no. 5, p. 943-948, May 2005.
. Electron Energy. Iv. 29, no. 4, p. 1881-1893, April 2014.
[6] B. Macy, Y. Lei, norPilawa-Podgurski, "A Resonant based in Ga V 25, 25 V to 100 V Gain-based Dickson switched-capacitor converter with 1011 W / in3 (61.7 kW / L) power density," Proc. IEEE Appl. Electron Power Conf. Expo., 2015, p. 1472-1478.
[7] Y. S. Lee and Y. Y. Chiu, "Flexible converter / converter / converter," Electron. Lett., Ivol. 41, no. 25, pp. 1403– 1405, Dec. 2005.
[8] V. A. K. Prabhala, P. Fajri, V. S. P. Gouribhatla, B. P. Baddipadiga, no-
UM. Ferdowsi, "A DC-DC converter with a high level of electrical power and two input stages," IEEE Trans. Electron Energy., Iv. 31, no. 6, pp. 4206-4215, Jun. 2016.
[9] M. Uno, "A low-power converter that converts a converted capacitor converter and a compatible pwm converter pwm," Proc. 35th Int. Telecom-mun. Power Conf. 'Smart Power Ef ficiency', Hamburg, Germany, 2013, p. 1-6.
[10] H. Liu noF. Li, "A high-performance novel converter with a variety of quasi operating power variables," IEEE Trans. Electron Energy., Iv. 31, no. 7, pp. 5030-5039, Jul. 2016.
[11] Y. Ye and K. W. E. Cheng, "A family of PWM converters converting single phase," IEEE Trans. Electron Energy., Iv. 28, no. 11, pp. 5196-5205, November. 2013.
[12] A. Abramowitz, B. Zhao, and K. M. Smedley, "High Level Strengthening One Platform for the Development of Photovoltaic Applications," IEEE Trans. Electron Power. Iv. 31, no. 5, p. 3550-3558, May 2016.
[13] Y. P. Hsieh, J. F. Chen, T. J. Liang, and L. S. Yang, converting Novel-high-up DC-DC. Ind. Electron. Iv. 60, no. 4, pages 1473
2013.
[14] H. C. Liu no. Li, "Novel high-up DC-DC converter and integrated inductor network for continuous power system," IEEE Trans. Electron Power., IV. 30, no. 12, p. 6476-6482, Dec. 2015.
. Electron Power. Iv. 30, no. 8, p. 4255-4263, Aug. 2015.
[16] T. J. Liang, S.M. Chen, L. S. Yang, J. F. Chen, no-A. Ioinovici, "The Ultra-converter converter is converted to DC-DC converter with a disc connected to other power sources," says IEEE Trans. Cyst., IV. 59, no. 4, pp.864-874, April 2012.
[17] K. C. Tseng, J. T. Lin, no. C. Huang, "Equilibrium connector of medium compact medium size including inductor power source," IEEE Trans. Electron Power., IV. 30, no. 2, p. 574-581, February 2015.
[18] Y. T. Jang and M. M. Jovanovich, "The power amplifier is connected to the internal power signal of the PFC front pipe," IEEE Trans. Electron Power., IV. 22, no. 4, pp. 1394-1401, Jul. 2007.
[19] X. Hu no. Gong, "The high converter receives a DC-DC converter that combines the integrated techniques with the diode-capacitor," IEEE Trans. Electron Power., IV. 29, no. 2, pages 789-800, February 2014.
[20] Y. P. Hsieh, J. F. Chen, T. J. Liang, and L. S. Yang, the respondents act as a Novel high-up DC-DC with integrated systems and a switched-capacitor for continuous power system, ”said IEEE Trans. Electron Power., Iv. 26, no. 12, pp. [26] S. M. Chen, M. L. Lao, Y. H. Hsieh, T. J. Liang, no-K. H. Chen, “A modified novel-inductor-inductor DC-DC supplier with its advent,” IEEE Trans. Ind. Appl., IV. 51, no. 1, p. 309-314, Jan./Feb. 2015.
[27] Design of TL5001 PWM controller, Texas In strum. Dallas, TX, 1995.
[28] Y. ye and K. W. E. Cheng, "Analysis and efficiency of switched-capacitor Power converter with parasitic resistance," IEEE Trans. Power Electron., [Online]. Available: http://ieeexplore.ieee.org/document/7470460/
To ensure uniformity of treatment among all contributors, other forms may not be substituted for this form, nor may any wording of the form be changed. This form is intended for original material submitted to AJCT and must accompany any such material in order to be published by AJCT. Please read the form carefully.
The undersigned hereby assigns to the Asian Journal of Convergence in Technology Issues ("AJCT") all rights under copyright that may exist in and to the above Work, any revised or expanded derivative works submitted to AJCT by the undersigned based on the Work, and any associated written, audio and/or visual presentations or other enhancements accompanying the Work. The undersigned hereby warrants that the Work is original and that he/she is the author of the Work; to the extent the Work incorporates text passages, figures, data or other material from the works of others, the undersigned has obtained any necessary permission. See Retained Rights, below.
AUTHOR RESPONSIBILITIES
AJCT distributes its technical publications throughout the world and wants to ensure that the material submitted to its publications is properly available to the readership of those publications. Authors must ensure that The Work is their own and is original. It is the responsibility of the authors, not AJCT, to determine whether disclosure of their material requires the prior consent of other parties and, if so, to obtain it.
RETAINED RIGHTS/TERMS AND CONDITIONS
1. Authors/employers retain all proprietary rights in any process, procedure, or article of manufacture described in the Work.
2. Authors/employers may reproduce or authorize others to reproduce The Work and for the author's personal use or for company or organizational use, provided that the source and any AJCT copyright notice are indicated, the copies are not used in any way that implies AJCT endorsement of a product or service of any employer, and the copies themselves are not offered for sale.
3. Authors/employers may make limited distribution of all or portions of the Work prior to publication if they inform AJCT in advance of the nature and extent of such limited distribution.
4. For all uses not covered by items 2 and 3, authors/employers must request permission from AJCT.
5. Although authors are permitted to re-use all or portions of the Work in other works, this does not include granting third-party requests for reprinting, republishing, or other types of re-use.
INFORMATION FOR AUTHORS
AJCT Copyright Ownership
It is the formal policy of AJCT to own the copyrights to all copyrightable material in its technical publications and to the individual contributions contained therein, in order to protect the interests of AJCT, its authors and their employers, and, at the same time, to facilitate the appropriate re-use of this material by others.
Author/Employer Rights
If you are employed and prepared the Work on a subject within the scope of your employment, the copyright in the Work belongs to your employer as a work-for-hire. In that case, AJCT assumes that when you sign this Form, you are authorized to do so by your employer and that your employer has consented to the transfer of copyright, to the representation and warranty of publication rights, and to all other terms and conditions of this Form. If such authorization and consent has not been given to you, an authorized representative of your employer should sign this Form as the Author.
Reprint/Republication Policy
AJCT requires that the consent of the first-named author and employer be sought as a condition to granting reprint or republication rights to others or for permitting use of a Work for promotion or marketing purposes.
GENERAL TERMS
1. The undersigned represents that he/she has the power and authority to make and execute this assignment.
2. The undersigned agrees to indemnify and hold harmless AJCT from any damage or expense that may arise in the event of a breach of any of the warranties set forth above.
3. In the event the above work is accepted and published by AJCT and consequently withdrawn by the author(s), the foregoing copyright transfer shall become null and void and all materials embodying the Work submitted to AJCT will be destroyed.
4. For jointly authored Works, all joint authors should sign, or one of the authors should sign as authorized agent
for the others.
Licenced by :
Creative Commons Attribution 4.0 International License.
