The higher-voltage line will have longer insulators and the line conductors will be further apart. And the symbol for kilovolt is 'kV', not 'kv'.
The clearance between 33-kV line (not 'phase'!) conductors depends on whether they are rigid (e.g. busbars) or can move (e.g. overhead lines); whether they are insulated or in air; etc.. So there are several 'clearance' distances. All are published on the internet -so you can do a search to find out for yourself.
Star (or 'wye') connected alternators have a phase voltage of 6.35 kV, and a line voltage of 11 kV. Incidentally, it's 'kV', not 'KV'.
The clearance depends on the voltage and would be defined in the electrical regulations in your country. <<>> The minimum horizontal spacing of conductors on the same supporting structure not exceeding 15 kV and not over a span of 50 metres (164 feet) is 400 mm (16 inches).
Yes, many parts of the US use 13.2 kV in primary line distribution systems. That is phase to phase. Phase to ground is 7620 V.
Ground clearance132 kv - 6100 mm220 kv - 7015mm400 kv - 8840mm765 kv - 15000mm
West Bengal, Jharkhand
It isn't. In the UK, transmission and distribution voltages are 400 kV, 275 kV, 132 kV, 66 kV, 33kV, and 11 kV.
no it no restricted
The standard voltage for transmission is about 115 to 1,200 kV (long-distance transmission). The extreme high voltages are measured more than 2,000 kV and it is exists between conductor and ground.Answer for UKThe standard transmission voltages in the UK are 400 kV and 275 kV. Primary distribution voltages are 132 kV and 33 kV, and secondary distribution voltages are 11 kV and 400 V. These are all line voltages -i.e. voltages measured between line conductors.
400KV transmission line surge impedence loading is depent upon the conductor type but its arount 600mw400KV transmission line surge impedence loading is depent upon the conductor type but its arount 600mw.Permissible Line Loading as per CEA Standards+/- 500 kV HVDC bi-pole line=Pole Capacity X Number of Pole in service765 KV line having 4 X 686 sq. mm conductor =2250 MW per circuit765 KV line having 4 X 686 sq. mm conductor operating at 400 kV =614 MW per circuit400 KV line having 2 X 520 sq. mm conductor with shunt reactor =410 MW per circuit400 KV line having 2 X 520 sq. mm conductor without shunt reactor =533 MWper circuit400 KV line having 2 X 520 sq. mm conductor operating at 220 kV =155 MW per circuit220 kV line =132 MW per circuit132 kV Line =50 MW per circuitsource:http://www.mahatransco.in/oa/draft_procedure_calculation_transmission_availability.shtm
The higher-voltage line will have longer insulators and the line conductors will be further apart. And the symbol for kilovolt is 'kV', not 'kv'.
It varies, according to their height, and the landscape (i.e. the levels of the ground) between towers, as well as upon any restrictions on where towers may be built. The determining factor is to ensure that the ground clearance of the conductors remain above their regulation clearance.
To calculate the capacity in megawatts of a 400 kV power line, you need to consider the current carrying capacity of the line. This is typically based on factors such as conductor size, ambient temperature, and the type of insulation used. Once you have the current carrying capacity, you can use the formula P = V x I to calculate the power capacity in megawatts, where P is power in MW, V is voltage in kV (400 kV in this case), and I is current in amperes.
Phase to phase clearance should be around 11.5 inches.
The clearance between 33-kV line (not 'phase'!) conductors depends on whether they are rigid (e.g. busbars) or can move (e.g. overhead lines); whether they are insulated or in air; etc.. So there are several 'clearance' distances. All are published on the internet -so you can do a search to find out for yourself.
In the UK a line of pylons carrying the supergrid at 400 kilovolts can carry up to about 2000 Megawatts. Pylons also carry circuits working at lower voltages, 275 and 132 kV, 66 kV in some places, and on small pylons 33 kV.