Home > High Voltage Power Cables > 64/110kV XLPE insulated corrugated Aluminum shielded Cable

HV-XLPE-insulated-corrugated-Aluminum-shielded-Cable

64/110kV XLPE insulated corrugated Aluminum shielded Cable

Application

High voltage power cables are designed for transmitting electrical power at voltages above 35kV. These cables are crucial for power transmission and distribution networks, connecting power plants to substations and distributing electricity across vast distances.

Construction

Conductor: Copper Or Aluminum
Conductor Screen: Semi-conductive tape+Semi-conductive Compound
Insulation: XLPE (Cross-linked Polyethylene)
Insulation Screen: Semi-conductive Compound
Wrapping: Semi-conductive water block tape
Metallic Screen: Corrugated aluminum sheath
Sheath: PE

Main Characteristics

Operating Temperature: -30°C to +90°C
Short Circuit Temperature: +250°C
Overload Temperature: +130°C (100h per year maximum)
Minimum Installation Temperature: -20°C

Specification

IEC 60840, Power cables with extruded insulation and their accessories for rated voltages above 30 kV (U=36 kV) up to 150 kV (U=170 kV).

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Conductor		Nominal insulation thickness	Insulation dia.	Al.sheath thickness	Nominal sheath thickness	Overall dia.	Approx.mass kg/km		DC resistance at 20℃ Ω/km		Capacitance at 20℃
Nominal cross section	Diameter	Nominal insulation thickness	Insulation dia.	Al.sheath thickness	Nominal sheath thickness	Overall dia.	Approx.mass kg/km		DC resistance at 20℃ Ω/km		Capacitance at 20℃
mm²	mm	mm	mm	mm	mm	mm	CU	AL	CU	AL	μF/km
1×240	18.4	19	59.2	2	4	85.6	7889	6429	0.0754	0.125	0.141
1×300	20.6	18.5	60.4	2	4	86.8	8538	6694	0.0601	0.1	0.151
1×400	23.4	17.5	61.2	2	4	87.6	9303	6939	0.047	0.0778	0.167
1×500	26.6	17	63.4	2	4	89.8	10447	7415	0.0336	0.0605	0.194
1×630	30	16.5	65.8	2	4.5	93.2	11861	7982	0.0283	0.0469	0.21
1×800	34	16	68.8	2	4.5	96.2	13653	8698	0.0221	0.0367	0.222
1×800	35	16	71.1	2	4.5	98.5	13985	9029	0.0221	0.0367	0.231
1×1000	39	16	75.1	2.3	4.5	106.1	16858	10640	0.0176	0.0291	0.256
1×1200	42.6	16	78.7	2.3	5	110.7	18879	11517	0.0151	0.0247	0.271
1×1400	45.2	16	81.3	2.3	5	113.3	20930	12330	0.0129	0.0212	0.286
1×1600	48.5	16	84.6	2.3	5	116.6	22964	13189	0.0113	0.0186	0.299
1×1800	50.8	16	86.9	2.3	5	118.9	25161	14024	0.0101	0.0165	0.312
1×2000	54	16	90.1	2.3	5	122.1	27274	14900	0.009	0.0145	0.327
1×2200	57.4	16	93.5	2.3	5	125.5	29407	15796	0.0083	0.0135	0.345
1×2500	61.2	16	97.3	2.3	5	129.3	32472	17005	0.0072	0.0127	0.362

Application and case display

FAQ

What is the application of Armored vs. Unarmored Cables?

How do you calculate the minimum bending radius of cables?

Why do cable prices vary significantly among suppliers within the same region?

What are the weight limits for different types of packages?

What is the validity period for the offer of cable?

Longitudinal Water Blocking vs. Lateral Water Blocking?

A longitudinally water blocking cable is designed with a barrier to prevent the spread of moisture along its length. Longitudinal water blocking stops water from migrating along the cable's core, typically between the conductor strands, insulation layers, or metallic screens. Lateral water blocking ensures that water cannot penetrate the cable in the event that the sheathing is pierced or damaged. Radial water blocking prevents water from penetrating the cable's outer sheath or insulation layers, thereby stopping it from entering the cable structure entirely. Longitudinal water blocking can be achieved through various methods, including the application of water-blocking tapes and powders. These are frequently located on either side of a metallic screen and conductor. Lateral water blocking is typically accomplished by applying a layer of aluminum/polyester tape to the underside of the outer sheath.

What is the purpose of a metallic shield in MV and HV cables?

Medium and high voltage power cables, typically those in circuits exceeding 2kV, usually feature a shield layer made of copper or aluminum tape. Similar to their use in low voltage cables, metallic wires and tapes are employed to prevent electromagnetic interference. These shields effectively neutralize or significantly diminish the field currents surrounding the conductor or core. The capacitive and inductive charging currents induced under normal operating conditions are subsequently grounded by the metallic screen.

What is the minimum order quantity for the product?

The minimum order quantity for low and medium voltage cables is 200 meters, whereas for high voltage cables, it is 2000 meters. Should the order quantity fall below the MOQ, however, if the factory has stock, we can still supply it.

Flame Retardant Cables VS Fire Resistant Cables?

Both types of cables are crucial in enhancing the likelihood of escape and survival in the event of a fire and are often confused with one another. However, there is a fundamental distinction between flame retardant cables and fire resistant cables. Flame retardant cables are engineered to inhibit the spread of fire to adjacent areas. On the other hand, fire resistant cables are specifically designed to preserve circuit integrity and ensure functionality during a fire, under specified conditions, aiding both evacuees and firefighters.

What is the application of Armored vs. Unarmored Cables?

Armored cables are suitable for use in hazardous environments, such as underground installations, areas with high moisture levels, and areas prone to mechanical damage. Unarmored cables are suitable for less demanding applications, such as inside walls or other protected locations.