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Analysis of High Temperature Low Sag Conductors Used for High Voltage Transmission 1876 6102 © 2016 The Authors Published by Elsevier Ltd This is an open access article under the CC BY NC ND license ([.]

Available online at www.sciencedirect.com ScienceDirect Energy Procedia 90 (2016) 179 – 184 5th International Conference on Advances in Energy Research, ICAER 2015, 15-17 December 2015, Mumbai, India Analysis of High Temperature Low Sag Conductors used for High Voltage Transmission Subba Reddy B* and Diptendu Chatterjee High Voltage Laboratory, Dept of Electrical Engg, Indian Institute of Science, Bangalore-560012, India Abstract Presently there is a continuous demand for the electric power consumption across the globe, however with the existing distribution lines are reaching critical limits of ampacity and sag, it has become difficult in finding corridors to construct new overhead lines in many industrialized countries including India Replacing the existing ACSR conductors with high temperature high current low sag (HTLS) conductors almost of the same diameter is one of the recent methods The present work a parametric study is conducted for steady state surface temperature, thermal time constant, change of emissivity, absorptivity etc for various ACSR and HTLS conductors using the developed computer code which is in accordance with IEEE Std.738 Some experimental study is also conducted and the results obtained are presented © 2016 The Authors Published by Elsevier Ltd This is an open access article under the CC BY-NC-ND license © 2016 The Authors.Published by Elsevier Ltd (http://creativecommons.org/licenses/by-nc-nd/4.0/) Peer-reviewunder under responsibility ofthe organizing committee of ICAER Peer-review responsibility of the organizing committee of ICAER 2015 2015 Keywords: HTLS conductors; ampacity;ACSR; low sag;Simulation; Experimentation Introduction The increase in power requirement is becoming a great challenge for the utilities in terms of cost and capacity where the existing lines have reached their maximum limit One of the solutions is the installation of a parallel structure like the existing towers, but this is not an economical solution The other way to find a cost-effective and more viable solution is in adopting high temperature low sag (HTLS) conductors for distribution systems [1] These conductors are different from conventional conductors in terms of material or structure or both _ * Corresponding author Tel.: +91-080-22932550; fax: +91-080-22932550 E-mail address: reddy@ee.iisc.ernet.in 1876-6102 © 2016 The Authors Published by Elsevier Ltd This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/) Peer-review under responsibility of the organizing committee of ICAER 2015 doi:10.1016/j.egypro.2016.11.183 180 B Subba Reddy and Diptendu Chatterjee / Energy Procedia 90 (2016) 179 – 184 The significance of HTLS conductors is they can carry 2.5 times the current that of the conventional ACSR conductors of same size and can withstand higher temperature (>200°C) with less sag One of the several advantages of HTLS over conventional ACSR is by re-conductoring an existing line with HTLS conductor the power delivery capacity can be increased But an HTLS conductor for long transmission is not recommended as it will cause higher voltage drop and power loss due to high current So increasing voltage level will be wise Several HTLS projects are being planned and implemented throughout the world including India [1, 2] The study of HTLS conductor was first initiated by Douglass [3] explaining the practical applications used for Connecticut Light and Power Company Later Alwar et al [4] have discussed about conventional ACSR conductors and the composite core conductors for low sag at high temperature IEEE Standard 738 [5] explains several factors that affect the temperature of bare overhead conductor The equations to find the current temperature relationship are given in this standard Several researchers [6-9] discussed about the emissivity, radial temperature distribution, corrosion and effective radial thermal conductivity in bare solid and stranded conductors Ravi Gorur [10] characterised the composite cores for HTLS conductors and studied surface temperature vs time curve, core temperature with current, with emissivity, absorptivity, thermal conductivity etc in accordance with IEEE Std 738[5] Further Harvey and others [11-15] studied temperature creep and sag-tension performance of HTLS conductors Recent IEEE Standard 1283[16] gives the guidelines for determining the effects of high temperature operation on conductors, connectors and accessories It describes possible adverse impact on operating overhead transmission line at high temperatures Gerald et al [17] discussed about how HTLS conductors can be a solution to the ever increasing power demand A technical report [18] describes the structure and properties of aluminium conductor composite reinforced (ACCR) conductors Researchers [19-24] have used different models for calculation of various parameters for HTLS conductors Recently several planned projects [25] using HTLS conductors are being implemented in the country Hence this work was initiated with the view that the data obtained will be useful for further implementation of projects as well as in enhancing the current literature Simulation Study In the present work, simulation studies are carried based on IEEE-738 Standard [5] The study consist of a developed Matlab code to simulate: Surface temperature variation with time for a given current level, variation of surface temperature with different parameters like ambient temperature, absorptivity and emissivity of the conductor material, variation of temperature along the radius of the conductor etc Separately (i) a graphic user interface (GUI) is developed for use in optimal design of different transmission and distribution accessories to be used for HTLS conductors which simulates temperature variation with current and different parameters also (ii) Simulation of magnetic field near the conductor due to increased current in case of HTLS conductors is attempted The technical details of various types of HTLS and ACSR conductors used for the present work are given in table below: Table Specification of conductors used for simulation HTLS1 HTLS2 HTLS3 28.14 28.62 28.118 Details Overall Dia (mm) ACSR 28.12 HTLS4 31.77 Resistance per length at 25deg C (ohm/km) 0.0728 0.0554 0.0674 0.0702 0.0431 Resistance per length at 75deg C (ohm/km) 0.0869 0.0662 0.0741 0.0843 0.0511 Heat Capacity per length (W-sec /m-C) 1309 756 1177 1296 1495 Following assumptions were made for the estimation of current and temperature: Ambient Temperature=40 degree centigrade; Velocity of wind=.61 meter/sec; Absorptivity=.5; Angle of the flow of wind with conductor axis=90 degree; Emissivity=.5; Day number of the year=161; Altitude=0 meters; Latitude=43; Azimuth of line=90 degree; Time of the day=11 a.m 181 B Subba Reddy and Diptendu Chatterjee / Energy Procedia 90 (2016) 179 – 184 Simulation Results The equations specified in [5] and the assumptions made, the thermal response and parametric variation of temperature is presented The thermal response of one ACSR and different HTLS conductors at 1750 Ampere is given in Fig.1 Variation of steady state surface temperature of ACSR and different HTLS conductors with emissivity and ambient temperature at 1000 Ampere are presented in Fig.2 The variation of steady state surface temperature with both emissivity and absorptivity at 1000 Ampere for ACSR and HTLS conductor is given in Fig For the desired surface temperature it is possible to get the operating point and fix the emissivity and absorptivity value of the conductor to get the desired temperature From the results it is seen HTLS conductors perform better over ACSR 120 Steady State Temperature (in deg C) Surface Temperature (in deg C) 200 180 160 140 120 100 ACSR HTLS-1 HTLS-2 HTLS-3 HTLS-4 80 60 40 0.5 1.5 time(minutes) 2.5 110 100 90 80 60 50 20 Fig Thermal time response for a step current of 1750 A ACSR HTLS-1 HTLS-2 HTLS-3 HTLS-4 70 25 30 35 40 45 Ambient Temperature (in deg C) 50 55 Fig Variation of Steady State Surface Temperature of with Ambient Temperature at 1000A 115 135 110 120 130 125 130 120 120 115 110 110 105 100 100 95 90 90 80 0.2 0.4 0.5 0.6 0.8 85 Steady State Temperature (in deg C) Steady State Temperature (in deg C) 140 105 110 100 100 95 90 90 85 80 70 80 0.2 0.4 0.8 absorptivity absorptivity emissivity 75 0.5 0.6 emissivity (a) ACSR (b) HTLS Fig Variation of Steady State Surface Temperature with emissivity and absorptivity at 1000A A Matlab based graphical user interface (GUI) has also been developed where in the environmental conditions, conductor dimensions, accessories material properties etc, given as input to get the optimal dimension of the accessories, and the time response of the conductor temperature Estimation of magnetic Fields The HTLS conductors operate at a higher current level, hence produce a proportionally higher magnetic field A 3D magnetic field simulation is carried out using a commercially available FEM software COMSOL Multiphysics®[26] The magnetic field near the region of the conductor has been estimated with the distance Both the cross-sectional plot and 3-D plot of the magnetic field for single and double conductor setup are presented 182 B Subba Reddy and Diptendu Chatterjee / Energy Procedia 90 (2016) 179 – 184 International guidelines [27] for the permissible magnetic field through human body both for continuous and discontinuous application help in deciding the approximate height of the conductors from ground level Simulation of magnetic fields in this work includes contour and 3-D magnitude plot of the magnetic field in the cross sectional surface of single and double line For all the cases, current through all the conductors is assumed to flow 1750 Ampere and the region of interest is up to meters in all the direction perpendicular to the axis of the lines Magnetic field contours for single and for the double transmission conductors are estimated Fig.4 shows for double line Similarly the magnitude of the magnetic field in cross-sectional surface of the conductor for double lines in 3-D are shown Fig respectively It is seen nearer to the conductor the magnetic fields are very high and reduce with the distance Fig.4 Magnetic field contours due to double lines each carrying 1750 Ampere Fig.5 Magnitude of magnetic field in the cross sectional surface of double lines each carrying 1750 Ampere Experimentation: Results and Discussions The experimental arrangement is shown in Fig.6, consists of a specially fabricated towers of height 1.5 meters having a span length of 6.5meters with a provision for conductor tension A specially fabricated high current source of 6kVA, 2000A is used for the experiments Two connecting leads of 25mm x40mm rectangular cross-section aluminium busbars of length 3.5meters (approx) are used For temperature measurement non contact type laser instrument and a testo make thermal imager model 875-II were employed Various samples of ACSR Conductors: Bersimis, Zebra, Moose along with HTLS Conductors: GTZ ACSR GAP Conductor, INVAR Moose, ACSS Curlew etc were used for the experiments Also HTLS conductor accessories like Mid-Span compression Joint, End Joint, Repair Sleeve, T- Connectors etc, were evaluated Two types of experimentation (short term and long term) were carried out on all the types of HTLS conductors and accessories Fig.6 Experimental arrangement (ACSR & HTLS) Fig.7 Typical measurement using thermal imager For short term experimentation the conductor is connected in between the two towers with span of 6.5 meters and the end terminations suitably connected with the bus-bars to the high current generator to provide a closed path (Fig.6) For ACSR conductors, the input current is varied from to 600 Amps in steps 0f 100 Amps after every minutes The temperature is recorded at different points on the conductor, busbars, end terminations etc For temperature measurement a thermal imager Testo-875II model was used along with non contact laser based B Subba Reddy and Diptendu Chatterjee / Energy Procedia 90 (2016) 179 – 184 instrument A typical measurement carried out on one of the sample using thermal imager is shown in Fig.7 From the measurements it was observed the temperature was higher mainly at the connecting joints In case of HTLS conductors input current is varied from to 1000 Amps in steps of 100 Amps after a gap of minutes and the values of temperature are recorded with the laser and also thermal imager Similarly for the experimentation on conductor accessories, the experimental setup remains same except the accessories are connected suitably between the towers using conductor joints and appropriate sleeves The long term experimentation was planned to obtain the thermal time constant for different ACSR and HTLS conductors using the same electrical connections as used in short term experiments For ACSR conductors a step input current of 400 Amps is applied and the surface temperature of the conductor is measured at every 10 seconds up to minutes and the temperature variation with time is obtained Then the applied current is reduced and switched off and allowed to cool down for 30 minutes The experiment is repeated for 500 Amps and 600 Amps respectively and the values of temperature variation are obtained In case of HTLS conductors a step current input of 400 Amps is applied and the surface temperature of the conductor is measured at every 10 seconds till minutes and temperature variation with time is obtained Then the system is cooled down for 30 minutes and the experiment is repeated for 500Amps, 600 Amps and 1000 Amps respectively Similar experiments were carried out for various accessories and the values obtained are reported Experiments for HTLS were limited to 1100A as it was seen that temperature was high near the connecting joints The results obtained are analyzed and presented individually Variation of steady state surface temperature of different ACSR and HTLS conductors with currents is presented in Fig.8 and variation of steady state surface temperature for different HTLS conductors accessories with current is shown in Fig.9 (a) ACSR (b) HTLS Fig.8 Variation of steadyy state surface temperature for different ACSR/HTLS Conductors with Currents p Fig.9 Variation of steady state surface temperature of different HTLS accessories with current Conclusions In the present work effort has been made to study and compare the performance of different types of HTLS and ACSR conductors A new experimental facility was established for the investigations It was seen for the application of same current, the steady state surface temperature of the HTLS conductor is lesser than that of the ACSR conductor of similar rating The thermal time constant is low for HTLS conductors in comparison to the ACSR conductors of similar rating as it depends on resistivity, radial thermal conductivity and shape/surface of the conductor The difference in average temperature between core and strand is lower in case of HTLS conductors It is not more than degrees for application of 1750 Amps, while for the same in case of ACSR conductor it is nearly about 183 184 B Subba Reddy and Diptendu Chatterjee / Energy Procedia 90 (2016) 179 – 184 10 degrees With the change in emissivity, absorptivity and ambient temperature the change in steady state surface temperature of HTLS conductors are similar to that of the ACSR conductors With increased emissivity, surface temperature of the conductor decreases and with increased absorptivity, surface temperature of the conductor increases The accessories subjected to same current level acquire less temperature than the conductor Magnetic field near the vicinity is similar for both ACSR and HTLS conductors, but only the magnitude proportionally increases because of the higher current in case of HTLS conductors References [1] [2] [3] [4] [5] [6] [7] [8] [9] [10] [11] [12] [13] [14] [15] [16] [17] [18] 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Part II, pp 970-976 D A Douglass, “Radial and Axial Temperature Gradients in Bare Stranded Conductors,” IEEE Transactions on Power Delivery, April 1986, Vol 1, No 2, pp 7-15 W Z Black, S S Collins, J F Hall, “Theoretical Model for Temperature Gradients within Bare Overhead Conductors,” IEEE Transactions on Power Delivery, Vol 3, No 2, pp 707-715,April 1998, V T Morgan, “The Radial Temparature Distribution and Effective Radial Thermal Conductivity in Bare Solid an Stranded Conductors,” IEEE Transactions on Power Delivery, July 1990, Vol 5, No 3, pp 1443-1452 R Gorur, R Oslen, “Characterization of Composite Cores for High Temperature-Low Sag (HTLS) Conductors,” Final Project Report, PSERC Publication 09-05, July 2009 J R Harvey, R E Larson, “Use of Elevated-Temperature Creep Data in Sag-Tension Calculations,” IEEE Trans Pow App and Systems, March 1970, volume: PAS-89, Issue: 3, Part: Part I, Page(s): 380-386 J Bradbury, P Dey, G Orawski, K H Pickup, “Long Term Creep Assesment for over 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2006 (from web) Ir Zahrul Faizi bin Hussien, “Electric Power Transmission,” Power Electronics Handbook, 2011 Karabay, S, “ACSS/TW aerial high-temperature bare conductors as a remedy for increasing transmission line capacity and determination of processing parameters for manufacturing,” Materials and Design, 2009 Piccolo, A, “Thermal rating assesment of overhead lines by Affine Arithmatic,” Electric Power System Research, 2004-11 Kopsidas, Konstantinos and Simon M Rowland, “A Performance Analysis of Reconductoring an Overhead Line Structure,” IEEE Transactions on Power Delivery, 2009 Lijia Ren, Xiuchen Jiang, Gehao Sheng, Wu Bo, “Design and calculation method for Dynamic Increasing Transmission Line Capacity,” WSEAS Transactions on Circuits and Systems, May 2008, Vol 7, Issue 5, pp 348-357 (www.wseas.us) Silva, A.A.P and J.M.B Bezerra, “Applicability and limitations of ampacity models for HTLS conductors,” Electric Power Systems Research, 2012 http://www.indiaworldenergy.org/pdf/T&D%20Report_PGCIL.pdf, “Transmission and Distribution in India,” 2010 Comsol Multiphysics Inc, Version 4.3 © 1998-2012 “ICNRP Guidelines for limiting exposure to time varying electric and magnetic fields”, Health physics, Vol.74, pp 494-522, April 1998 ... of HTLS conductors is attempted The technical details of various types of HTLS and ACSR conductors used for the present work are given in table below: Table Specification of conductors used for. .. applications of High- temperature low sag Transmission Conductors? ??, Technical report Power delivery consultants, Inc, 2004 A Alwar, E J Bosze, S R Nutt, “A Composite Core Conductor for Low Sag at High Temperatures,”... studied temperature creep and sag- tension performance of HTLS conductors Recent IEEE Standard 1283[16] gives the guidelines for determining the effects of high temperature operation on conductors,

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