Home > Low Voltage Power Cables > NA2XRY 0.6/1kV Aluminum XLPE insulated Steel wire armored Cable

NA2XRY 0.6/1kV Aluminum XLPE insulated Steel wire armored Cable

Application

These power cables are used for electricity supply in low voltage installation systems. They are well adapted to underground use in industrial applications with an additional mechanical protection. They are suitable for laying Indoor, tunnel, cable trench, shaft or buried laying. The cable can withstand mechanical external forces and a certain tensile force, it widely used in transformer stations, electric power plants and industrial plants.

Construction

Conductor: Aluminum, class 1 or class 2, solid or stranded, circular or circular compacted conductors
Insulation: Cross-linked polyethylene XLPE
Inner sheath: Polyvinyl chloride PVC
Armour: Non-magnetic steel wire
Binder: Non-hygroscopic material
Outer sheath: Polyvinyl chloride PVC

Main Characteristics

Good electrical and mechanical properties.
Cross-linked polyethylene insulation allows greater power capacity under any operating condition, minimum dielectric losses, high insulation resistance.
The PVC outer sheath allows an adequate resistance to oil and abrasion.

Specification

IEC 60228 Conductors of insulate cables
IEC 60502-1 Power cables with extruded insulation and their accessories for rated voltages from 1 kV(Um=1.2 kV) up to 30 kV(Um=36 kV) – Part 1: Cables for rated voltages of 1 kV (Um=1.2 kV) and 3 kV(Um=3.6 kV)

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No. of cores and nominal cross section	Min. Number of wires	Nominal insulation thickness	Nominal Non-magnetic steel wire diameter	Nominal sheath thickness	Approx. overall Diameter	Approx. weight	Max. DC resistance of conductor at 20℃
No.×mm²	No.	mm	mm	mm	mm	kg/km	Ω/km
1×10	6	0.7	0.8	1.4	12.1	253	3.08
1×16	6	0.7	0.8	1.4	12.9	299	1.91
1×25	6	0.9	0.8	1.4	14.5	374	1.2
1×35	6	0.9	0.8	1.4	15.5	430	0.868
1×50	6	1	1.25	1.5	18.1	630	0.641
1×70	12	1.1	1.25	1.5	19.8	767	0.443
1×95	15	1.1	1.25	1.6	21.8	914	0.32
1×120	15	1.2	1.6	1.7	24.3	1176	0.253
1×150	15	1.4	1.6	1.7	26.2	1356	0.206
1×185	30	1.6	1.6	1.8	28.4	1575	0.164
1×240	30	1.7	1.6	1.9	31.1	1876	0.125
1×300	30	1.8	1.6	2	33.7	2170	0.1
1×400	53	2	2	2.1	38.3	2875	0.0778
1×500	53	2.2	2	2.2	41.8	3419	0.0605
1×630	53	2.4	2	2.3	46.1	4085	0.0469

Application and case display

FAQ

Longitudinal Water Blocking vs. Lateral Water Blocking?

What temperature can high-temperature resistant cables reach, and what are their application scenarios?

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

Is a flame-retardant cable also fire resistant?

Flame Retardant Cables VS Fire Resistant Cables?

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 validity period for the offer of cable?

Typically, the offer is valid for 7 to 30 days, and the price will be adjusted according to the cost of raw materials and the exchange rate.

How do you calculate the minimum bending radius of cables?

The bend radius refers to the curved shape in which an electrical cable can be bent or curved without sustaining damage. To determine the minimum bend radius for cables, apply the following formula: Minimum Bend Radius = Cable Outer Diameter×Cable Multiplier. For example, if the outer diameter of a cable is 20mm, its minimum bending radius would be 20mm×6 = 120mm. Conversely, if an armored cable has an outer diameter of 30mm, its minimum bending radius would be 30mm×12 = 360mm.

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 temperature can high-temperature resistant cables reach, and what are their application scenarios?

High-temperature resistant cables are engineered to function within a wide temperature range, spanning from -50°C to +260°C, depending on the cable's specific type and construction. Silicone rubber-insulated cables can withstand temperatures up to 180°C, whereas fluoroplastic insulated cables are designed to endure temperatures as high as 200°C to 260°C over extended periods. They are widely used in steel metallurgy, power, petrochemicals, aerospace, and industrial kilns for power transmission and equipment control in high-heat environments.