论文信息 - A 21-level (line-to-line) BTB system based on series connection of sixteen converter-cells for power flow control: experimental verifications by a 200-V, 10-kW laboratory system

A 21-level (line-to-line) BTB system based on series connection of sixteen converter-cells for power flow control: experimental verifications by a 200-V, 10-kW laboratory system

A 21-level (line-to-line) self-commutated BTB (back-to-back) system based on series connection of sixteen converter-cells has attractive features as follows: i) Both active and reactive powers can be controlled independently even in transient states, ii) The BTB system produces almost sinusoidal voltage at the AC side without performing PWM (pulse-width-modulation) control, so that no harmonic filter is required, iii) The BTB system provides an active-power response as high as 3 ms. This work presents experimental verifications of the self-commutated BTB system for the purpose of achieving power flow control in transmission systems. Experimental results obtained by a 200-V 10-kW laboratory prototype confirm effectiveness and validity of both the proposed system configuration and control strategy developed in this paper.

H. Fujita | H. Akagi | M. Hagiwara

[1] S. Sugimoto,et al. Development and testing of prototype models for a high-performance 300 MW self-commutated AC/DC converter , 1997 .

[2] Hirofumi Akagi,et al. Instantaneous Reactive Power Compensators Comprising Switching Devices without Energy Storage Components , 1984, IEEE Transactions on Industry Applications.

[3] Makoto Hagiwara,et al. Performance of a self-commutated BTB HVDC link system under a single-line-to-ground fault condition , 2003 .

[4] A. Ekstrom,et al. Multiterminal HVDC systems in urban areas of large cities , 1998 .

[5] Shigeru Tanaka,et al. A Novel Control of Self-Commutated Converters for Large Power Applications , 1998 .

[6] Boon-Teck Ooi,et al. Force commutated HVDC and SVC based on phase-shifted multi-converter modules , 1993 .

[7] Hirofumi Akagi,et al. Analysis and design of a DC voltage-controlled static VAr compensator using quad-series voltage-source inverters , 1996 .

[8] G. Asplund. Application of HVDC Light to power system enhancement , 2000, 2000 IEEE Power Engineering Society Winter Meeting. Conference Proceedings (Cat. No.00CH37077).

[9] Makoto Hagiwara,et al. An approach to regulating the DC-link voltage of a voltage-source BTB system during power line faults , 2003 .