Published: 2020-01-24
ISBN: 978-91-7929-897-5
ISSN: 1650-3686 (print), 1650-3740 (online)
This paper discusses that the significant voltage drop under load condition is the big problem of distribution networks, because it limits the transfer capability of distribution lines. A utilization of the compact lines technology allows a significant increase in the transfer capability of distribution lines. Important developments for controlling over voltage and conductor resonances in recent decades gave the possibility to reduce the distances between phases. The modern distribution lines can be optimized with respect to their electric parameters in comparison with normal distribution lines, and by this increase the capacity in energy transmission.
ACCR. Power Conductor Accelerated Testing Facility (PCAT), ACCR Technology Description, November 2003.
Alcola Conductor Accessories. Transmission Accessories, 2003.
G. N. Alexandrov and H. Heidari. Equalization of overhead Ch. RI, "Heida" Increasing Lind Voltage.
Aluminum Conductor Composite Reinforced, Technical Notebook, 3M, March 2003.
A. Chakir and H. Koch. Thermal Calculation for Buried Gas –Insulated Transmission Lines (GIL) and XLPE-Cale, In IEEE Winter Power Meeting 2001, Columbus, 2001.
A. Chakir and H. Koch. Long Term Test of Buried Gas Insulated Transmission Lines (GIL). In IEEEWPM 2002 New York, 2002.
A. Clerci and M. Landonio. EHV Compact Lines – a new solution. In CIGRE, 1991.
CRIEPI, Report: Development of Make 66 to 154 kV Overhead Compact Transmission Lines (Part7) – Study on Mechanical Stresses to 154 kV Insulation Arms on Full-Scale Actual Test. CRIEPI Rep. W95037
Dennis Doss. Double your transmission capacity without changing existing towers. In Electric light 7 and Cable, August 2002.
Gh. Heidari. Equalization of overhead transmission line capacity different classes of voltage. In PSC 95, Tehran, Nov. 1995.
Gh. Heidari and G. N. Alexandrov, Increasing line voltage or sub conductors number each phases. In CIGRE, Paris, France, Sept. 1996.
Gh. Heidari and Maziar Heidari. Effect of land price on transmission line design. In CIGRE, Sept. 2002.
C. G. Heningen, G. Kaul, H. Koch, A. Scheuette, and R.Plath. Electrical and Mechanical Long-Time Behaviour of Gas – Insulated Transmission Lines. In CIGRE, 08/2000.
T. Hiller and H. Koch. Gas Insulated Transmission Lines (GIL): proven technology with new performance. In Xiamen Switchgear Seminar, China, 1997
T. Hiller and H. Koch. Gas–Insulated Transmission Lines for high power transmission over long distances. In EMPT, Singapore, 1998a.
T. Hiller and H. Koch. Gas –insulated Transmission Lines (GIL): A solution for the power supply of metropolitan areas. In CEPSI, Thailand, 1998b.
H. Koch and A. Schuette. Gas Insulated Transmission over long distances. In EPSR, Hong Kong, 1997.
Inventions & Innovations. Development of a Composite–Reinforced Aluminum Conductor, Project Fact Sheet, 1999.
H. B. Markus, P. Vestner, Diego F. Sologuren-Sanchez, Bodo A. Bruhl, and Paul F. Coventry. Dimensioning criteria and test result for a polymer enclosed gas insulted line. In CIGRE, 2000.
F. Sganzerla, J. A. A., Casagrande, and D. B. Galia. Electron are Brazila – 500 kV and 230 kV Compavr Lines: Design and G or subconductors number in each phase, CIGRE, Paris, France, Sept.1996.
