umer LT PVC Armoured / Un-Armoured Power & Control Cables -

LT PVC Armoured / Un-Armoured Power & Control Cables

LT PVC Armoured Un-Armoured Power & Control Cables 2
LT PVC Armoured Un-Armoured Power & Control Cables 3
LT PVC Armoured Un-Armoured Power & Control Cables 4
Single & Multicore Aluminium Cables 1
Single & Multicore Aluminium Cables 2
Armoured / Un-Armoured Power & Control Cables

DP DEELUX POWERCAB is manufacturer of  a wide range of Armoured Cables, Armoured Power Cables, Armoured Electrical Cables, PVC Armoured Cables and XLPE Armoured Cables. XLPE means cross-linked polyethylene or vulcanized polyethylene. The basic material is low density polyethylene. Polyethylene is a thermoplastic material consisting of long chain of hydrocarbon molecules. At elevated temperatures these molecules tend to move relative to one another so that the material becomes increasingly deformable and will eventually melt at the temperature around 110°C.

The process of rubber the polyethylene molecules can be cross-linked. The process of cross-linking or vulcanization consists of producing chemical bonds at interval between the long molecular chain to give a ladder effect which prevents slippage between molecules as a result of cross-linking the material becomes heat resistant and does not soften at higher temperatures. Further it has better resistance to stress cracking and good resistance to ageing in hot air. With the change of structure there is no adverse effect on electrical properties.


The most acceptable metals are copper and Aluminium due to their higher conductivity & ductility.As Copper has got higher affinity for sulphur, it corrodes in the atmosphere where sulphur fumes are present. In these conditions tinned copper should be used. Aluminium oxide film which is always present on aluminum conductor surface acts as barrier and it protects the Aluminum conductor from corrosion in fumes laden atmosphere.


The most economical construction for conductor is solid conductor i.e. conductor made of one single wire. As the area conductor increases, solid conductor becomes stiffer and hence difficult to handle in this case stranded construction is adopted. Here the conductor is made of number of strands. This construction provides more flexibility. Where crimping of lugs is required, the conductor has to be of stranded construction only. To economies in insulating material, weight and overall diameter, shaped conductors are employed in bigger sized cables. Here the stranded conductor is shaped in to a segment of a circle so that when all the cores are laid, they form a complete circle. These segments are identified as 2 Core- 180 degrees, 3 Core- 120 degrees, 4 Core- 90 degrees, 3.5 Core- 100/60 degrees. I.S.1554 permits solid conductor construction up to 10 in aluminium and up to 6 in copper. It permits the use of shaped conductors for size from onwards.


The PVC covering over conductor is called insulation and is provided by extrusion process only. The insulated conductor is called core.I.S.:1554 permits two types of PVC insulation as follows:

1)Insulation with type A PVC Compound as per IS: 5831 which is suitable for 70°C continuous operation.

2) Insulation with type C PVC Compound as per IS: 5831 which is suitable for 85°C continuous operation.


The cores are laid up with suitable lay. The final layer always has a right hand lay i.e. if you look along the cable, the cores move to your right hand.


Inner sheath is provided over the laid up cores. It is provided to give circular shape to the cable and it provides bedding for the armouring.

I.S. 1554 permits following two methods of applying the inner sheath of any thermoplastic material i.e. PVC, Polyethylene, etc.

  1. EXTRUDED INNER SHEATH:Here the inner sheath is provided by extrusion of Thermoplastic over the laid up cores. This type of Innersheath is generally provided in cables having round cores i.e. in control cables and power cables upto 10 sizes. This type of the inner sheath also acts as a water barrier between cores and outer sheath. Is case of a puncture in the outer sheath the water cannot reach to the cores and hence we recommend that cables for outdoor underground uses should have extruded inner sheath.
  2. TAPPED INNER SHEATH:Here the inner sheath is provided by wrapping a thermoplastic tape over the laid up cores. It is generally employed in cables having sector shaped cored i.e. multi core cables of and above.

This method saves a process and hence manufactures always provide this type of inner sheath unless the purchase specifications ask for extruded inner sheath.


In case of armoured cables, generally galvanized steel wire / strip is provided over the inner sheath is multi core cables and Aluminium Round wire or Aluminium strip over the insulation in single core cables. It provides mechanical protection inside cores and it carries earth return current in case of short circuit of a core with armour.

As per I.S. 1554 (Part-1) 1988, round wire armouring is provided in cable, where calculated diameter under armour is up to 13 mm. Above this the armouring is either with round wire or strip of size 4 mm 0.80 mm. As strip construction is economical, the manufactures always provide steel strip armouring unless wire armouring is specially specified.

In long run of cables and in case of mines, round wire armouring is must, as strip construction provide higher resistance to earth fault current and sometimes this current may not be sufficient to operate the circuit breaker in case of earth fault.

In mines, the resistance of the armour in no case should exceed the resistance of the main core by more than 33% for safety reasons. To achieve this, sometimes tinned hard drawn copper wires are required to be used along with galvanized steel wires. Sometimes two layers of Round steel wire or Steel Strip are applied in opposite direction with barrier tape in between are provided to give extra protection.

In case of single core for use in AC circuits, the material for armouring has to be nonmagnetic, as in this case the return current is not passing through the same cable and hence it will not cancel the magnetic lines produced by the current. These magnetic lines which are oscillating in case of AC current will give rise to eddy current in magnetic armouring and hence armouring will become hot, and this may lead to the failure of the cable. Generally hard drawn aluminium wires / strip are used for armouring in this case.


The PVC covering the armouring in case of armoured cables and over the inner sheath in case of un-armoured cables is called outer sheath.

I.S. 1554 specifies nominal and minimum thickness of outer sheath for UN –armoured cables and only minimum thickness of outer sheath for armoured cables.

It permits the following types of outer sheath PVC compounds.

  • Outer sheath with type ST1 PVC compound as per IS: 5831, which is suitable for 70°C continuous operation.
  • Outer sheath with type ST2 PVC compound as per IS: 5831, which is suitable for 85°C continuous operation.

PVC has got fire retardant properties due to its halogen content. The fire in the cable gets extinguished immediately on removal on the fire source.

In the modern Power, Chemical, Fertilizer and Cement plants many PVC cables are bunched in the cable shaft or on cable trays. In case of fire in these cables, the fire becomes self sustaining. Moreover due to the burning of PVC a dense corrosive smoke is emitted which makes fire fighting very difficult, due to poor visibility and toxic nature of the smoke. HCL content of the smoke, not only damages other costly equipment lying nearby, but also penetrates the RCC and corrodes the steel reinforcement. Due to this there is an extensive to the property.

To overcome these deficiencies FRLS i.e. Fire Retardant Low Smoke PVC was developed. If required, we can provide Fire Retardant Low Smoke (FRLS) PVC Inner Sheath and / or outer sheath. This PVC compound, apart from meeting the requirements of Type ST2 as per IS-5831, has got better fire retardant properties and it emits lower smoke and acid fumes when it catches fire.