COMPANY PROFILE Universal Cables Limited (UCL) was established in the year 1962 as a modern mass production unit for the manufacture of paper insulated power cables in technical collaboration with the world's largest cable producer BICC, UK. Late Shri. M. P. Birla, who had adorned the chair of the company from the day of its inception for over 25 years enabled the company to flourish in a highly competitive world, while distinguishing itself by the latest technological tie ups with the foremost leaders in the world of this industry and the most up-to-date technology.
special applications such as Flamuni range FRLS Cable, 1.1kv XLPE Cable, etc. In 1983, UCL embarked on a joint venture with MPAVN for manufacture of Jelly Filled Telephone Cable in technical collaboration with one of the world's leading manufacturers of Telephone Cable, M/s Ericsson Cable AB of Sweden. This unit is named M/s. VINDHYA TELELINKS LIMITED and is situated at Rewa, only 50 KM away from the Power Cable Plant at Satna. Since 1985, M/s. ASEA BROWN BOVERI CABLE AB, SWEDEN is further assisting this company in manufacture of Fluoro-plastic Cables, specifically for very high temperature operation and high frequency signalling circuitry.
Universal Cables Limited entered into a collaboration agreement with M/s. ASEA BROWN BOVERI CABLE AB of Sweden in the year 1977 for the manufacture of Crosslinked Polythene Power Cable for the first time in the country. The Company is the foremost manufacturer of XLPE Cable with modern dry cured dry cooled process for voltage range extending from 1.1 kv to Extra High Voltage. Under the collaboration agreement of M/s ASEA BROWN BOVERI CABLE AB, Sweden, UCL brought in complete know how of compounding of Polymer and produced complete range of dielectrics presently used in all special cables. UCL emphasizes on in-house Research & Development. R & D programme is mainly directed to applied research for product development, process development and technological upgradation. R & D Laboratory of UCL is a recognized unit of Department of Scientific and Industrial Research of Govt. of India. This Laboratory has developed many new Cables for
In 1993, UCL & VTL jointly entered into the field of optical communication by way of manufacturing Optical Fibre Cables in technical and financial collaboration with M/s Ericsson Cables AB of Sweden under the name M/s BIRLA ERICSSON OPTICAL LIMITED (BEOL). UCL also exports its products to various countries of the world, which has earned much recognition for its export efforts. M/s. Universal Cables Limited is a vibrant progressive company, a leader in its field of activities, serving the aspiration of the nation in the field of Power Development.
1.0 INTRODUCTION: After a decade of satisfactory experience in the manufacture of high voltage XLPE cables and intensive R&D, Unistar XLPE cables range now includes Extra High Voltage XLPE cables. They are suited to withstand a service voltage range from 66 KV upto and including 145 KV. This marks a quantum jump both in respect of manufacturing technology and quality assurance techniques. This development has been possible because of very active all round support from our technical collaborator ASEA BROWN BOVERI CABLES AB, of Sweden-acknowledged world leaders in development and manufacture of Extra High Voltage XLPE cables. The manufacturing plant and testing laboratories of the company have been upgraded with large capital investment to adopt the technology. 'Unistar' EHV XLPE cables are designed for bulk transmission of electrical energy with minimum transmission losses for an effective service life of 50 years or more.
2.7 Conductive outer layer: A conductive outer layer facilitates testing of the nonmetallic outer sheath. This test is important to ensure the physical integrity of the cable from time to time, be it at the factory, after transportation, directly after laying upon completion of the installation, or periodically thereafter. The construction details of three designs of EHV XLPE cables are shown in figure 1 to 3:
Fig. 1 Copper Wire screen, standard design:
2.0 CABLE DESIGN: 2.1 Conductor: Conductor is made of stranded copper or aluminium having high compactness and smooth surface finish. 2.2 Conductor Shield: This is applied over the conductor with a semiconducting compound which not only eliminates the risk of electrical discharge at the interface between conductor and insulation but also presents a very smooth protrusion free interface with the insulation to eliminate any localised stress concentration. 2.3 Insulation: Insulation is composed of a special super-clean grade of crosslinkable polythene and applied over the conductor screen to the desired thickness in a void free manner. 2.4 Core Screen: A semi-conducting layer similar to conductor screen is applied over the insulation for similar purpose and this is followed by a semi-conducting non-woven water barrier tape when required. Over this tape metallic part of the screen is applied in the form of spiral wrapping of copper wires. When the cable is installed in waterlogged area or underwater, metallic part of the screen is often impervious metal sheath in place of copper wires. 2.5 Outer sheath for unarmoured cables: This is composed of ST-2 grade PVC to IS: 5831/84/ IEC-840 or black polythene with PE/AL moisture barrier tape depending upon the installation condition. 2.6 Armoured Cables: If required by installation conditions, further protection of on-ferrous metal wire armouring and extruded PVC sheath may be applied.
Fig. 2 Copper Wire screen, water tight design: (i) Radial water sealing is achieved by a corrosion resistant metal polyethylene laminate. (ii) Longitudinal water sealing is achieved by a water swellable tape applied over the copper wire.
Fig. 3 Lead sheath screen: (i) Radial water sealing is achieved by a corrosion resistant-lead sheath. (ii) Longitudinal water sealing is achieved by a water swellable tape applied under sheath. 3.0 CONSTRUCTION: Construction details of Unistar EHVXLPE cables are given in tables 1 to 3.
4.0 TECHNICAL PARAMETERS: Technical parameters of Unistar EHV XLPE cables are given in tables 4 to 8. 5.0 PROCESSING: Unistar EHV XLPE cables are processed in a modern triple extrusion manufacturing line with 'ASEA' dry cure and dry cooling arrangement. The material handling system is completely mechanised and the plant is airpressurised with clean air to avoid any contamination. The processing parameters are determined by computer programming and the entire line of processing is controlled, from a central control console with the help of closed circuit TV.
testing. A specially trained quality assurance team works round the clock for maintenance of the quality at an optimum level. The Quality of Unistar EHV XLPE cable also has been verified by independent testing at Central Power Research Institute, Bangalore. 7.0 INSTALLATION & ACCESSORIES: Service Engineers of the company have been specially trained for installation of EHV XLPE cables together with suitable accessories and they provide all assistance to the customers for this purpose. Accessories for indoor and outdoor termination and also for straight through joint, are being supplied by KABELDON AB of Sweden - a subsidiary company of our collaborator ABB Cables AB. Details of accessories and their installation instructions are available on request. The Company also accepts complete turn-key jobs for the supply installation, testing and commissioning of EHV XLPE Cables.
Fig. 4 Catenary continuous vulcanizing extrusion line. 6.0 TESTING & QUALITY ASSURANCE: Unistar EHV XLPE cables are tested to IEC 840, SS 4241417 and IS - 7098 (III) for routine and type tests. Besides this EHV XLPE cable samples are subjected to long term evaluation testing programme and accelerating ageing for verifying the compliance to the expected designed life. The Quality Control of EHV XLPE cables during manufacture is very critical and expert supervision is required for raw material testing, in process checks and also for final
Fig. 6. Outdoor termination.
Fig. 7. We can help you to install a maintenance-free cable network. 8.0 TECHNICAL SERVICE:
Fig. 5. The products are supported by qualified research and development.
A team of trained service Engineers will be happy to assist the customers for selection of EHVXLPE cables of the right design and accessories needed for the intended application. They will also provide all necessary after-sales service.
TABLE-1 SINGLE CORE CABLES – 66 KV Area
Insulation Thickness
(sq. mm.)
Approx. Conductor Diameter (mm)
185 240 300 400 500 630 800 1000
16.2 18.6 20.6 23.6 26.7 30.2 35.0 38.5
12.0 12.0 12.0 12.0 12.0 12.0 12.0 12.0
Screen Area (sq. mm)
(mm)
Outer Sheath Thickness (mm)
Approx. Overall Diameter (mm)
2.5 2.6 2.7 2.8 2.9 3.0 3.1 3.2
53.0 56.0 58.0 61.0 65.0 69.0 76.0 79.0
35 35 35 35 35 35 35 35
Approx Wt/KM With Al. With Cu. Conductor Conductor (Kg) (Kg) 2450 2750 3000 3450 3900 4450 5400 6100
3500 4100 4700 5650 6600 8000 ---
TABLE-2 SINGLE CORE CABLES – 110 KV Area
Insulation Thickness
(sq. mm.)
Approx. Conductor Diameter (mm)
400 500 630 800 1000
23.6 26.7 30.2 35.0 38.5
17.5 17.0 16.5 16.0 16.0
Screen Area (sq. mm)
(mm)
Outer Sheath Thickness (mm)
Approx. Overall Diameter (mm)
3.2 3.3 3.4 3.4 3.6
75.0 78.0 80.0 86.0 90.0
95 95 95 95 95
Approx Wt/KM With Al. With Cu. Conductor Conductor (Kg) (Kg) 5050 5400 5950 6900 7650
7200 8150 9500 ---
TABLE-3 SINGLE CORE CABLES – 132 KV Area
Insulation Thickness
(sq. mm.)
Approx. Conductor Diameter (mm)
400 500 630 800 1000
23.6 26.7 30.2 35.0 38.5
21.0 20.0 20.0 19.0 19.0
Screen Area (sq. mm)
(mm)
Outer Sheath Thickness (mm)
Approx. Overall Diameter (mm)
3.5 3.5 3.6 3.6 3.8
80.0 84.0 87.0 95.0 98.0
95 95 95 95 95
Approx Wt/KM With Al. With Cu. Conductor Conductor (Kg) (Kg) 5800 6100 6750 7600 8400
TABLE-4 CONDUCTOR RESISTANCE Cross Section (Sq. mm) 165 240 300 400 500 630 800 1000
Maximum D. C. Resistance at 20ºC (Ohm/KM) Aluminium Copper 0.164 0.125 0.100 0.0778 0.0605 0.0469 0.0367 0.0291
0.0991 0.0754 0.0601 0.0470 0.0366 0.0283 0.0221 0.0176
7950 8800 10300 ---
TABLE-5 APPROXIMATE CAPACITANCE (uF/KM) Area (Sq. mm)
66 KV
Rated Voltage of the Cable 110 KV
132 KV
185 240 300 400 500 630 800 1000
0.16 0.18 0.19 0.21 0.23 0.25 0.28 0.30
0.16 0.18 0.20 0.23 0.24
0.15 0.16 0.18 0.20 0.21
TABLE-6 APPROXIMATE INDUCTANCE FOR SINGLE CORE CABLES LAID IN TREFOIL FORMATION (mH/KM) Area (Sq. mm)
66 KV
Rated Voltage of the Cable 110 KV
132 KV
185 240 300 400 500 630 800 1000
0.42 0.40 0.39 0.38 0.36 0.35 0.34 0.33
0.41 0.40 0.38 0.37 0.36
0.43 0.41 0.40 0.38 0.37
TABLE-7 APPROXIMATE DIELECTRIC LOSSES, WATT/KM/PHASE, AT RATED VOLTAGE Area (Sq. mm)
66 KV
Rated Voltage of the Cable 110 KV
132 KV
185 240 300 400 500 630 800 1000
73 82 86 95 104 113 127 136
203 228 253 291 304
272 290 326 363 381
TABLE-8 APPROXIMATE CHARGING CURRENT, AMPS/KM, AT RATED VOLTAGE Area (Sq. mm)
66 KV
Rated Voltage of the Cable 110 KV
132 KV
185 240 300 400 500 630 800 1000
1.9 2.1 2.3 2.5 2.7 3.0 3.3 3.6
3.2 3.6 4.0 4.6 4.8
3.6 3.8 4.3 4.8 5.0
SCREEN BONDING METHODS BOTH-ENDS BONDING Both-ends bonding of screens, means that the screens are connected and earthed at both ends of the cable route. In this case a current will appear in the screen. This will cause losses in the screen, which reduces the cable current-carrying capacity. These losses are smaller for cables in trefoil formation than in flat formation.
SINGLE-POINT BONDING Single-point bonding of screens, means that the screens are connected and earthed only at one end of the cable route. In this case, a voltage will be induced between screen and earth, but no current will appear. This induced voltage is proportional to the cable length and current. Single-point bonding can only be used for limited route lengths.
In this case, a voltage will be induced between screen and earth, but no current will appear. The maximum induced voltage will appear at the link boxes for crossbonding, see figure. This method permits a cable current-carrying capacity as high as with single-point bonding but longer route lengths than the latter. It requires screen separation and additional link boxes, though. CURRENT RATING The cables should at least have a cross section adequate to meet the system requirements for power transmission capacity. The evaluation of the overall cost of a cable system should include the capitalized cost of losses, both on load and no load losses. Since the cost of losses is normally evaluated based on the marginal cost of energy and installed power, overall optimization may often lead to using larger cable cross sections than the minimum ones meeting current carrying requirements. On load losses are basically the ohmic losses in the conductor and the metallic screen. The XLPE cables can be loaded continuously to a conductor temp, of 90°C. However, to keep a safety margin, or to keep the losses lower, or to avoid possible thermal instability due to drying out the surrounding soil, it may be advantageous to limit the operating temp, to, say, 65°C. No load losses are basically the dielectric losses. Here it is the choice of dielectric material that counts, especially for application at 100 KV or more. Thanks to its small loss angle, XLPE presents much lower dielectric losses than paper or rubber as cable insulation material.
CROSS-BONDING Cross-bonding of screens, means that the screens belonging to adjoining cables are connected as in the figure.
The continuous current ratings given in tables 9 to 12 are calculated according to IEC Publ. 287 on the following conditions. Ground temp.
: 30°C
Ambient air temp.
: 40°C
Depth of laying (L)
:1.0Mtr.
Distance between cable axes laid in flat formation (S)
: 70 mm + De
Thermal resistivity of soil
: 150 °C cm/Watt.
TABLE-9 CURRENT RATING FOR 66 KV CABLES WITH ALUMINIUM CONDUCTOR Cross Section Cond- Screen uctor Sq. mm 185 240 300 400 500 630 800 1000
Sq. mm. 35 35 35 35 35 35 35 35
Cables in Ground Flat Formation SPB / CB
Cables in Air
Trefoil Formation
Both Ends
SPB / CB
Flat Formation
Both Ends
SPB / CB
Trefoil Formation
Both Ends
SPB / CB
Both Ends
65ºC 90ºC 65ºC 90ºC 65ºC 90ºC 65ºC 90ºC 65ºC 90ºC 65ºC 90ºC 65ºC 90ºC 65ºC 90ºC 235 275 310 355 405 460 525 590
300 350 395 450 515 590 665 745
220 250 280 310 345 380 415 445
280 320 360 400 445 490 545 585
225 260 295 335 385 440 495 545
285 330 375 430 490 560 630 700
225 260 290 330 380 430 485 530
285 330 370 420 485 545 615 685
305 360 415 480 555 650 745 850
410 485 555 645 755 880 1010 1160
295 335 385 440 505 575 650 720
395 460 525 610 695 795 905 1010
290 340 390 455 525 610 700 785
395 460 525 620 715 830 950 1075
290 340 390 450 520 600 685 770
395 460 525 610 710 820 935 1055
TABLE-10 CURRENT RATING FOR 66 KV CABLES WITH COPPER CONDUCTOR Cross Cables in Ground Cables in Air Section CondFlat Formation Trefoil Formation Flat Formation Trefoil Formation Screen uctor SPB / CB Both Ends SPB / CB Both Ends SPB / CB Both Ends SPB / CB Both Ends Sq. Sq. 65ºC 90ºC 65ºC 90ºC 65ºC 90ºC 65ºC 90ºC 65ºC 90ºC 65ºC 90ºC 65ºC 90ºC 65ºC 90ºC mm mm. 165 35 305 385 275 350 290 370 290 365 390 525 365 500 375 505 370 505 240 35 350 445 305 395 335 425 335 420 455 620 420 580 435 595 430 590 300 35 395 505 335 435 375 480 370 475 525 715 475 655 500 680 495 670 400 35 450 575 370 480 425 540 420 535 610 820 535 740 575 780 565 770 500 35 515 650 405 525 485 615 475 605 710 960 610 845 660 905 650 890 630 35 580 740 435 570 545 595 530 675 815 1110 685 950 755 1035 735 1015
TABLE-11 CURRENT RATING FOR 110 KV & 132 KV CABLES WITH ALUMINIUN CONDUCTOR Cross Cables in Ground Cables in Air Section CondFlat Formation Trefoil Formation Flat Formation Trefoil Formation Screen uctor SPB / CB Both Ends SPB / CB Both Ends SPB / CB Both Ends SPB / CB Both Ends Sq. Sq. 65ºC 90ºC 65ºC 90ºC 65ºC 90ºC 65ºC 90ºC 65ºC 90ºC 65ºC 90ºC 65ºC 90ºC 65ºC 90ºC mm mm. 400 95 350 445 275 360 335 420 325 415 480 645 425 580 450 610 440 600 500 95 400 510 300 390 380 485 365 470 555 750 475 650 525 705 510 690 630 95 455 580 320 420 430 550 415 525 645 875 530 735 605 815 580 795 800 95 520 665 345 450 490 620 460 590 765 995 585 810 690 935 660 905 1000 95 570 735 360 480 540 690 505 650 845 1145 645 900 775 1060 735 1015
TABLE-12 CURRENT RATING FOR 110 KV & 132 KV CABLES WITH COPPER CONDUCTOR Cross Cables in Ground Cables in Air Section CondFlat Formation Trefoil Formation Flat Formation Trefoil Formation Screen uctor SPB / CB Both Ends SPB / CB Both Ends SPB / CB Both Ends SPB / CB Both Ends Sq. Sq. 65ºC 90ºC 65ºC 90ºC 65ºC 90ºC 65ºC 90ºC 65ºC 90ºC 65ºC 90ºC 65ºC 90ºC 65ºC 90ºC mm mm. 400 95 445 560 320 415 420 535 405 515 610 815 505 695 570 770 550 750 500 95 505 645 335 440 475 610 445 580 705 950 555 775 655 890 625 915 630 95 570 730 360 470 535 685 500 645 810 1095 610 860 745 1020 710 975
RATING FACTORS 1. RATING FACTOR FOR CROSS SECTION OF METAL SCREEN: Single core cables in Trefoil Formation, Screen Bonded at Both Ends. For Singe Point Bonding or Crossbonding no rating factor applies. 1.1 Rating Factor for 66 KV Cables: Conductor Sq. mm.
Copper Screen Sq. mm.
Al.
Cu.
16
35
50
95
150
300
300 500 800 1000
185 300 500 630
1.01 1.01 1.02 1.02
1 1 1 1
0.99 0.99 0.99 0.98
0.98 0.97 0.92 0.94
0.97 0.95 0.92 0.90
0.95 0.92 0.88 0.84
1.2 Rating Factor for 66 KV Cables: Conductor Sq. mm.
Copper Screen Sq. mm.
Al.
Cu.
16
35
50
95
150
300
300 500 800 1000
300 500 630
1.03 1.04 1.06 1.08
1.02 1.03 1.04 1.06
1.01 1.02 1.03 1.04
1 1 1 1
0.99 0.98 0.97 0.96
0.97 0.95 0.92 0.90
2. RATING FACTORS FOR CABLES IN GROUND: 2.1 Rating Factor for Depth of Laying: Depth (Metre) 0.5 0.7 Rating Factor
1.10
1.05
0.9
1.0
1.2
1.5
1.01
1.0
0.98
0.95
2.2 Rating Factor for Thermal Resistivity of Soil: Thermal Resistivity 70 100 120 (ºC cm/Watt) Rating Factor 1.35 1.19 1.10 2.3 Rating Factor for Ground Temp.: Conductor Temp ºC 10 15 90 65
1.15 1.26
1.12 1.20
20 1.08 1.13
150
200
250
300
1.0
0.88
0.80
0.72
35
40
45
0.96 0.93
0.91 0.85
0.86 0.76
Ground Temperature ºC 25 30 1.04 1.07
1.0 1.0
2.4 Rating Factor for Groups of Cable in Ground: Number of Groups
Distance cc Between groups (mm)
1
2
3
4
5
6
7
8
9
100
1
0.76
0.67
0.59
0.55
0.49
0.49
0.47
0.46
200
1
0.81
0.71
0.65
0.61
0.56
0.56
0.53
0.52
400
1
0.85
0.77
0.72
0.69
0.64
0.66
0.63
0.62
600
1
0.88
0.81
0.77
0.74
0.71
0.72
0.70
0.69
800
1
0.90
0.84
0.81
0.79
0.76
0.77
0.75
0.75
2000
1
0.96
0.93
0.92
0.91
0.91
0.91
0.90
0.90
2.5 Rating Factors for Phase Spacing (one group in Flat Formation with Cross Bonded or Single Bonded Screen): Spacing ‘S’ mm
De
De + 70
200
250
300
350
400
Rating Factor
0.93
1
1.03
1.05
1.07
1.06
1.10
3. RATING FACTOR FOR CABLES INSTALLED IN PIPES IN THE GROUND Single Core Cables partially installed in separate Pipes*
Single Core Cables in separate Pipes.
Single Core Cables in a common Pipe.
0.94
0.90
0.90
The rating factor given for single core cables partially installed in separate pipes, applies only when a cable section between screen earthing points are partially laid in pipes under the following conditions - The cables are laid in trefoil formation over the major portion of the section - The pipes are laid in fiat formation - The pipe length is not more than 10% of the section between earthing points - One cable per Pipe - The Pipe diameter is two times the cable diameter. 4. RATING FACTOR FOR CABLES IN THE AIR: 4.1 Rating Factor for ambient air temp: Air Temp ºC
15
20
25
30
35
40
45
50
55
Rating Factor
1.25
1.21
1.16
1.11
1.05
1.0
0.94
0.87
0.81
OVER LOAD 105°C As infrequently as possible, the cables may be overloaded and the conductor temp. may reach upto 105ºC. Both occurrence and duration of these overloads should be kept to a minimum, though, in the interests of sparing the cable life Cyclic and emergency rating can be calculated through IEC: 833-2 EMERGENCY LOAD 130°C Upon emergency, the conductor temperature is allowed to rise upto 130°C However the duration of the emergency load should be restricted to not more that 50 Hours at a time and 500 Hours per year in order not to shorten the cable life substantially SHORT-CIRCUIT CURRENTS The permissible short-circuit current of a cable is determined by the maximum permissible conductor temperature (250°C), and by the duration of the short-circuit current At high peak currents the dynamic forces between the conductors must be taken into account Thermally maximum short-circuit currents Formula to calculate the thermally equivalent short-circuit current at different durations Where Ik = I1/tk Where Ik = short-circuit current during time tk I1 = short-circuit current for 1 s from Tables 13 and 14 tk = short-circuit durations. This formula is valid only in the time interval 0.2 - 5s.
TABLE-13 Max. Short-Circuit on the conductor during 1s. kA Conductor Temperature before Short Circuit
Cross Section Mm2 185 240 300 400 500 630 800 1000
Aluminium Conductor
Copper Conductor
65ºC
90ºC
65ºC
90ºC
19.2 24.8 31.1 41.4 51.8 65.2 82.8 104
17.5 22.7 28.3 37.8 47.2 59.5 75.6 94.5
29.0 37.6 47.0 62.7 78.4 98.7 125 157
26.5 34.5 42.9 57.2 71.5 90.1 114 143
TABLE-14 Max. Short-Circuit on the Screen during 1s. kA Metallic Screen Cross Section mm2
Metallic Screen Temperature before the Short Circuit
Copper Screen
Lead Sheath
50ºC
70ºC
16 25 35 50 95 150 300
110 170 240 340 650 1030 2070
3.4 5.4 7.5 11 21 32 64
3.3 5.1 7.1 10 19 30 60
Tablet 13 and 14 are based on the following formula
Where I i S t E K B
ot oi Mechanical forces from short-circuit currents Formula to calculate the dynamic forces between two conductors 2 F = 0.2 x is S Where is = peak current, kA S = centre – to - centre spacing between conductors, m F = force N/m Note : All figures given are non-binding and indicative only
= maximum short-circuit current, A = current density. A/mm2, 1s = conductor or screen cross section, mm2 = duration of short-circuit current, s = 1 0 for conductor = 1 2 typical for metal screens = 148 for Al, 226 for Cu and 41 for Pb = 228 for Al. 234 for Cu and 230 for Pb = final temperature, ºC = initial temperature ºC