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- 1-35KV Cu/Al XLPE SWA/STA Armored Power Cable
1.Voltage:1-35kv, 2.Conductor:Aluminum/Copper ,3.insulation:XLPE ,4. sheath:PVC/PE Armor:SWA/STA, 5.packaging: wooden drum,steel drum,oth... - ATA armoured power cable
1.ATA armoured power cable
2.Rated voltage U0/U3.6/6kv
3.temperature of cable conductor shall not exceed 250°C.
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ACCC
Introduction
ACCC Conductor /Aluminum conductor Carbon Fiber Composite Core Reinforced conductor
ACCC conductor is the newest type stranded conductor , usually used in the overhead power transmission lines.
It has double capacity of ACSR at the same conditions.
Increased Power Transfer
When compared to an ACSR that can be strung on the same towers, ACCC conductors will carry about 28% more annealed aluminum in
a trapezoidal configuration giving greatly increased conductivity; the carbon core provides increased strength and virtually eliminates high
temperature sag allowing more efficient operation at up to 180°C. This can double current capacity (ampacity) over the ACSR.
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Reduced High Temperature Sag
The coefficient of thermal expansion of ACCC conductor at its final condition is eight times less than typical ACSR, and the ACCC core
is approximately two and a half times lighter than steel. ACCC conductors sag very little due to thermal expansion which eliminates this
as a significant design consideration.
Energy Efficiency
Using more aluminum with better conductivity reduces losses at every temperature of operation. When operating as a High Temperature
Low Sag (HTLS) conductor, the higher operating efficiency can reduce line losses and their associated emissions by more than 35%. This
results in more power delivered to be sold and can result in lower power generation costs.
Reduced Tensions on Towers
Lower initial sag at normal tensioning allows for lowering initial tensions on weaker towers and during line upratings or allows designing for
smaller power towers on new lines.
Uprating lines and Building New Lines
Existing pathways can be reconductored with reduced, and often without, structural modifications; this reduces capital uprating costs and
time to completion. New lines can be constructed with reduced numbers of towers taking advantage of the ACCC conductor lower sag profile,
reducing tower capital costs significantly and time to completion. Often, better tower foundations can be sited due to the extra span reach,
increasing line strength and reducing costs and time.
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