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Uso de componentes naturais de edificações como parte integrante do sistema de proteção contra descargas atmosféricas - uma visão relativa aos danos físicos. / The use of structural parts of the buildings as part of the lightning protection systems - the physical damages aspects.Sueta, Hélio Eiji 09 December 2005 (has links)
Este trabalho apresenta alguns aspectos específicos sobre o tema proteção de estruturas contra descargas atmosféricas", principalmente no que se refere ao uso de partes estruturais das edificações como integrantes do sistema de proteção. São discutidos neste trabalho diversos pontos polêmicos referentes ao tema, tais como: captores especiais, o sistema dissipativo e o uso das ferragens das colunas de concreto armado como parte dos subsistemas de descida e de aterramento. São abordados, também, os principais danos que podem ocorrer nas edificações devido às descargas atmosféricas, principalmente quando a proteção utilizar partes naturais da estrutura, tais como: os telhados metálicos e as emendas das ferragens das colunas de concreto armado. Após uma verificação do estado da arte no assunto, onde são estudados diversos trabalhos, normas e livros sobre as características das descargas, sobre os danos oriundos das descargas, blindagens, medições de campos eletromagnéticos, distribuição de correntes e sobre a normalização e ensaios referentes à proteção de estruturas contra descargas atmosféricas, o assunto foi estudado em três partes que compõem os subsistemas do SPDA. No subsistema de captação, os danos em telhas metálicas e de concreto protendido foram estudados através de ensaios e verificações teóricas e, principalmente, experimentais. No subsistema de descida, o estudo experimental deu enfoque às emendas das ferragens e ao uso destas como descidas naturais. Finalmente, no subsistema de aterramento, as fundações das edificações foram estudadas através de verificações experimentais como parte do aterramento. Este trabalho acrescenta ao conhecimento atual sobre o assunto, diversas particularidades não contempladas nas normas e nas publicações mais recentes no que tange à proteção de estruturas contra as descargas atmosféricas utilizando partes naturais das edificações. / This work presents some specific aspects on the subject lightning protection of structures, mainly when the use of structural parts of the buildings as part of the protection systems is concerned. Several polemical issues are discussed, such as: special air-termination, the dissipation array system and the use of steel-reinforcing rods of the reinforced concrete columns as part of the down-conductor system and of the earth-termination system. Also treated is the main damage that can occur to the buildings due to lightning, mainly when the protection system uses the natural components of the structures, such as: the metallic rooftops and the joints of the steel-reinforcing rods of the reinforced concrete columns. After examining the state-of-the-art in the subject, which analyses several papers, standards and books about lightning characteristics, damage resulting from lightning, shieldings, measurements of electromagnetic fields, distribution of currents and about standardisation and tests related to the protection of structures against lightning, the subject was studied in the three parts that compose the lightning protection systems. In the air-termination system, the damage to metallic rooftops and to pre-stressed concrete rooftop tiles was studied by means of tests and theoretical and mainly experimental analyses. In the down-conductor system, the experimental study focused on the joints of the steel-reinforcing rods and on the use of these as natural down-conductors. Finally, in the earth-termination system, the foundations of the buildings were studied (as part of the grounding) through experimental analyses. This work adds to the current knowledge about the subject several particularities which are not observed in the standards or in the most recent publications concerning the lightning protection systems in buildings that use their natural components for this purpose.
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Καταπονήσεις σε ένα σύστημα αντικεραυνικής προστασίαςΣαραντίδη, Ελευθερία 18 June 2009 (has links)
Στόχος αυτής της εργασίας είναι η περιγραφή ενός συστήματος αντικεραυνικής προστασίας και η αναφορά στις καταπονήσεις που αυτό υφίσταται. Περιλαμβάνει επίσης τον υπολογισμό της αύξησης της θερμοκρασίας σε ηλεκτρικούς συνδέσμους υπό κρουστικό ρεύμα καταπόνησης / The aim of this diploma is the research in a lightning protection installation. Moreover a mathematical model and approximate equations are proposed, concerning the temprature rise estimation at electric couplings, during lightning discharges.
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The use of surge arresters in parallel for the lightning protection of pole mounted distribution transformers in Eskom.Chatterton, Baden George. January 2002 (has links)
Eskom (Electricity Supply Commission of South Africa) is the national electrical utility that provides the generation, transmission and distribution of electricity in South Africa. The majority of Eskom's electricity distribution is done with either 11 kV or 22kV electrical overhead networks. An unacceptable number of Eskom's pole mounted power transformers on these networks have been failing over the past six years in the Kwa-Zulu Natal region. The average transformer failure rate for the Distribution Eastern Region was calculated to be 2.4% per annum. International norms seem to indicate a transformer failure rate of between 0.5% and 1.0% per annum as acceptable. The estimated cost of these transformer failures was between R9 million and R13 million per annum for the Eastern Region. Eskom Distribution has seven regions and the total cost of these failures was considerable to the business. These transformer failures contributed an average of 5.3% per month of the Supply Loss Index (SLI) for the Eastern Region, with a maximum contribution of 14.5% per month of the SLI for the region. The SLI is an Eskom performance measure of the unavailability of supply of the networks. The Eskom plant performance database (NAPI) was statistically analysed in detail and a number of field investigations conducted at transformer installations that had failed in the past. Transformer earth electrode resistance measurements were taken in an attempt to identify the cause of these transformer failures. Local transformer manufacturers were consulted and a national transformer refurbishment company's database was analysed during the investigation as part of a holistic approach to the industry related dissertation. The main finding of the NAPI data analysis was that the majority of the transformers failed during lightning storm periods. Another similar Eskom investigation had a sample of failed transformers opened for internal inspection. Signs of lightning damage to either the primary side winding or the primary lead were found. The proposed failure hypothesis was that the transformers required additional lightning protection of the primary side to protect the transformer against lightning. It seemed that the current specification of the Eskom distribution class surge arresters was inadequate to offer sufficient lightning protection of the pole mounted transformers. Practical measures were implemented on existing Eskom 11 kV networks in the Glencoe area as part of an Eskom research project to reduce the high failure rates of transformers. Two experimental networks were established and one control network was used as a reference line. The project implementation was completed at the end of October 1999. The experimental project looked at applying additional primary side lightning protection of the transformers. The main emphasis of the lightning protection on the first network was the use of two distribution class arresters in parallel (double arrester configuration) for each transformer and an understrung conductor connected to the prior structure back from the transformer installation. The second network had the standard single arresters installed on the transformers. A 600mm wood path was placed in series with an earthed down conductor installed on each intermediate woodpole structure to ensure a basic insulation level of 300kV for the network. The control network also had single arresters installed and was a fully insulated network (no earthed down conductor on the woodpoles). Each network was carefully monitored in terms of equipment failures and the performance levels of each network was measured with installed voltage dip recorders near the individual network circuit breakers. The Eskom Lightning Position and Tracking System (LPATS) data was collected and analysed to quantify the lightning activity before the project implementation to that of after project implementation. For the period November 1999 to March 2002 not a single transformer or surge arrester had failed ,due to lightning on the double arrester and understrung conductor configuration experimental network. There were recorded transformer and surge arrester failures on the second experimental network and on the control network. It was found that the practical methods implemented on the networks did not have a negative impact on the performance levels of the networks. Laboratory work was conducted in the high voltage laboratory at the University of Natal, on various metal oxide varistor (MOV) blocks of opened up new and failed surge arresters. This was to determine the effect of MOV blocks in parallel under power frequency and current impulse conditions. In particular, to determine what the effect of parallel MOV blocks with different voltage-current (V-I) characteristics would have on the current sharing and energy absorption capabilities of the individual blocks. The work was performed to simulate the behaviour of two surge arresters in parallel as in the experimental project. The experimental project lines were modeled using the Alternative Transients Program (ATP) simulation package and various parametric studies performed in the single phase conductor simulations. Each network component (such as the line, transformer and surge arrester) and phenomena (such as the effect of corona, the transient earth electrode resistance and voltage flashover) were modeled. The effect of surge arresters in parallel and the use of an understrung conductor arrangement were quantified. A current sharing factor (k-factor) was introduced to quantify the sharing of currents through surge arresters in parallel with different V-I curves. The main finding from the impulse laboratory work was that current sharing between parallel MOV blocks became better at higher currents. This finding was supported by other research work findings, particularly in the field of nuclear fusion research with parallel arresters. The results of the ATP simulations showed that the experimental network with the parallel arresters and understrung conductor arrangement considerably reduced the energy absorbed by the individual arresters. The effect of the double arrester configuration was to reduce the energy absorbed by the individual arresters even with arresters with different V-I characteristics and different manufacturers. The understrung conductor arrangement was found to be the major contributor towards the reduction of the energy absorbed by the arresters. The equivalent circuit of a MOV block for transient studies was proposed and then simulated in ATP. The simulated results were compared to the measured waveforms obtained from the impulse laboratory work. A good agreement between the simulated and measured waveforms was obtained. For existing Eskom networks with high arrester and transformer failure rates, the double arrester (distribution class) configuration would be the most time and cost effective solution. The alternative of using a single station class arrester is not proposed due to the costs involved and the availability of stock. The understrung conductor arrangement did significantly reduce the energy absorbed by the arresters but due to high labour costs and time requirements this would not be recommended for existing networks. It is suggested that Eskom investigate this practical method for new lines to be built in high lightning areas. Even with arresters from different manufacturers, the use of the double arrester configuration would decrease the energy absorbed and hence reduce the risk of failure of the individual arresters protecting the transformer. This means that Eskom field staff can use different manufacturer arresters in parallel. This would be especially for times when replacing failed arresters or a faulty transformer under breakdown conditions and electrical supply has to be restored to the customer as soon as possible. It was proposed to perform arrester matching by ensuring that the both arresters were from the same manufacturer. / Thesis (M.Sc.Eng)-University of Natal, Durban, 2002.
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Protection Of Structures Against LightningFoya, Ufuk Candar 01 July 2004 (has links) (PDF)
This thesis analyses the lightning protection concept. After a brief introduction to lightning, lightning discharge process and the consequences of a lightning stroke, the worldwide standards for the protection of structures against lightning are analysed and compared in the scope of requirement for the lightning protection.
The lightning protection systems since Franklin are traced and the protection methods are re-arranged in the basis of rolling sphere method. after discussing the changing philosophy in lightning protection, cage method is examined and applications of cage method are done according to different protection levels.
This thesis seek an answer to the question such that which the safest method for the protection of structures against lightning according to new requirements would be.
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Estudo do desempenho de sistemas de aterramento frente às descargas atmosféricas em instalações de baixa e média tensão /Sant'Anna, Cezar José. January 2005 (has links)
Orientador: André Nunes de Souza / Banca: Geraldo Francisco Burani / Banca: Pedro da Costa Júnior / Resumo: O presente trabalho possui como linha mestra a apresentação de proposições técnicas para as instalações de baixa e média tensão na incidência de descargas atmosféricas, visando diminuir danos nos equipamentos elétricos dos consumidores. Para a realização dessas proposições foram estudados e analisados diversos casos relacionados ao sistema de aterramento recomendados pelas normas e publicações técnicas. A diretriz metodológica adotada nesta pesquisa incorporou estudos correlatos já consolidados, experimentos e também simulações computacionais. Os resultados obtidos foram analisados levando-se em conta a influência dos sistemas de aterramento e seus componentes, tais como: tipos de eletrodos, solo, tipo de condutor de descida e dispositivos de proteção contra surtos. / Abstract: The master line of this present study consists of the presentation of technical propositions related to low and medium tension installations in the incidence lightning, aiming to decrease damages on consumer's electrical equipment. For the accomplishment of those propositions, several cases related to the earthing systems recommended standards and publications have been studied and analyzed. The methodological directive adopted in the present research has been incorporated already consolidated correlate studies consolidated, experiments, as well as digital simulations. The results obtained have been analyzed taking into account the influence of the earthing systems and their components, such as: electrodes, soil, descending conductors and protection devices. / Mestre
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Comparing lightning polarity and cloud microphysical properties over regions of high ground flash density in South AfricaSimpson, Lee-ann January 2013 (has links)
Positive lightning flashes are known to be more intense and cause more damage than negative flashes, although positive flashes only occur about 10% of the time. This study expounds on cloud microphysical aspects of thunderstorms and investigates the occurrence, timing and location of ice particles within thunderstorms and correlates this to the occurrence of positive cloud-to-ground lightning events.
Satellite data obtained from the Meteosat Second Generation (MSG) satellite, were used to: 1) depict Cloud Top Temperatures (CTT) by considering Infra Red (IR) radiation with a wave length of 10.8μm, 2) compare results from the CTT with the Brightness Temperature Difference (BTD) calculated by subtracting IR10.8μm from IR8.7μm, 3) after the cloud particle phase was determined from the abovementioned comparison, the sum of cloud-to-ground lightning strokes over a 1-hour period around the time of a reported lightning fatality was compared with cloud microphysical properties and then 4) these results were further compared with the lightning polarity obtained from the South African Weather Service (SAWS) Lightning Detection Network (LDN) data set.
Four case studies were identified to investigate from the many available case study dates. These four cases occurred on 3 separate days namely: 1)22 November 2007,
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2) 10 February 2009 and 3) 29 October 2009. There were two fatal events reported on 22 November 2007 and therefore two cases studies were compiled for this one date. On 10 February 2009 over 250 insurance damage claims were honoured but no fatality was reported. The three case studies mentioned above were classified as primary case studies. The 29 October 2009 case was classified as a secondary, more generalized case which was chosen in order to test whether the results gained from the first three cases were indeed noteworthy.
Results gathered from two of the three primary case studies showed that the fatalities occurred when the most intense part of the thunderstorm was to the east of the location where the lightning struck the victims, although actual storm properties were not considered as being particularly severe. The lightning data for the primary case studies showed that the percentage of cloud-to-ground lightning was within 10% of the total number of strokes recorded for 22 November 2007, and above 10% for 10 February 2009. In the one secondary case study of 29 October 2009 the percentage of positive lightning was only between 2% and 4% of the total number of strokes recorded, which was significantly lower than in the three primary cases. A significant difference in cloud microphysics between the primary and secondary cases was the possible occurrence of super-cooled liquid water found in Cumulonimbus (CB) clouds in the secondary case. This could have been a determining factor for the difference in percentage of positive lightning between the primary and secondary case studies. / Dissertation (MSc)--University of Pretoria, 2013. / gm2014 / Geography, Geoinformatics and Meteorology / unrestricted
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Volcanic Electrification: A Multiparametric Case Study of Sakurajima Volcano, JapanSmith, Cassandra M. 02 April 2019 (has links)
Electrical activity at volcanoes has been recently recognized as a potential new remote sensing technique for plume-forming eruptions. Volcanic electrical activity takes place in the conduit and plume and therefore has the benefit of being a direct indicator of surface activity. This is unlike seismic signals, which indicate magma/gas movement underground, and infrasound signals, which indicate a surface explosion but not necessarily the formation of an ash plume. There are two distinct types of volcanic electrical discharges: volcanic lightning and continual radio frequency (CRF) impulses. This dissertation explores the relationships between these two electrical signals and other commonly monitored volcanic parameters. For volcanic electrical activity to be widely adopted into monitoring platforms it is important to understand how electrical discharges at volcanoes are related to other monitored signals. I present a case study of the electrical activity at Sakurajima Volcano, Japan. The lightning mapping array (LMA) is used to record both lightning and CRF. I relate CRF to ash properties and show that CRF corresponds to eruptions containing more juvenile magma that has undergone milling as it is transported out of the conduit. Seismic, infrasound, and video data are used in conjunction with multivariable statistical methods on a suite of electrical parameters to show that high levels of volcanic electrical activity are related to eruptions with large infrasound signals (> 107 J), high initial velocities (> 55 m/s), and relatively tall plume heights (> 1 km). Finally, an examination of globally detected lightning at Bogoslof Volcano, AK shows the potential for volcanic lightning in plume tracking (0-100 km), even after the end of the explosive phase of the eruption.
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A Nonlinear Statistical Algorithm to Predict Daily Lightning in MississippiThead, Erin Amanda 15 December 2012 (has links)
Recent improvements in numerical weather model resolution open the possibility of producing forecasts for lightning using indirect lightning threat indicators well in advance of an event. This research examines the feasibility of a statistical machine-learning algorithm known as a support vector machine (SVM) to provide a probabilistic lightning forecast for Mississippi at 9 km resolution up to one day in advance of a thunderstorm event. Although the results indicate that SVM forecasts are not consistently accurate with single-day lightning forecasts, the SVM performs skillfully on a data set consisting of many forecast days. It is plausible that errors by the numerical forecast model are responsible for the poorer performance of the SVM with individual forecasts. More research needs to be conducted into the possibility of using SVM for lightning prediction with input data sets from a variety of numerical weather models.
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Laboratory study on lightning performance of dissipation devicesMallick, Shreeharsh 08 August 2009 (has links)
The proponents of non-conventional lightning protection devices claim that these devices are superior to the conventional Franklin Rod. Lack of systematic study and insufficient field data make it difficult to compare the non-conventional lightning protection devices with the conventional ones. Previously, the performance of various air terminals was studied by comparing the emission current through various dissipation devices in the MSU High Voltage Laboratory. The study of emission current from the air terminals gives an idea about the space charge developing over them. However, it does not show the behavior of air terminals to attract or repel lightning strikes. The present study presents the measurements of critical flashover (CFO) voltage of the air terminals. The CFO voltage shows the ability of an air terminal to attract or reduce the chance of lightning strike to the protected object.
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Lightning Shielding Failure Analysis of Ultra High Voltage Power Transmission LinesDevadiga, Anurag A January 2015 (has links) (PDF)
In India, the natural energy resources (thermal and hydro) are unevenly distributed and are mostly present in the remote areas and the load centers are distributed across various regions of the country. Therefore high voltage lines have become necessary for the devel-opment of large interconnected power networks and for the reliable and economic transfer of power. The increase in electric power demand due to the electric load growth has lead to the expansion of the transmission systems to ultra high voltage levels. Presently, Ultra High Voltage (UHV) power transmission lines are being built to transfer large electric power to distant load centers from the generating stations. Increasing the line voltage increases the surge impedance loading, stability and the thermal capacity of the line.
Lightning is one of the major causes for the line outages and interruptions of UHV power lines. A lightning strike generates a very large voltage leading to insulator puncture, melting, burning and pitting of conductors and the supporting hardware. Lightning can lead to transient over-voltages thus leading to ash-over in the power transmission lines which are dangerous for the power equipments as well as for the human beings working in the vicinity. Ground wires are used for the protection of overhead power transmission lines against a lightning stroke. The overhead ground wires are installed such that the lightning attaches to it and shunts the lightning current to the ground through the tower, thus protecting the phase conductors. Shielding failure happens when the lightning strikes the phase conductor instead of the ground wires. Lightning shielding failure is a major con-cern in UHV lines due to their large height, very high operating voltage and wide exposure area of the phase conductors. The lightning over-voltages injected on the phase conductor (shielding failure) nally reaches the substation causing serious threat to the substation components and can lead to temporary or permanent outage of the power transmission system. There have been cases of very high shielding failure ash-overs of UHV lines and thus lightning attachment to power transmission lines need to be studied in detail to reduce the power system line outages.
Several models such as electro-geometric model (EGM) and leader progression model (LPM) have been developed to study the shielding failure of power transmission lines. EGM has been extensively used to obtain lightning attachment to power transmission lines but in recent years it is seen that EGM is unable to accurately predict the lightning attach-ment to UHVAC lines. The shielding failure rates obtained by EGM does not match with the observed shielding failure rate for UHV lines. For this reason LPM is considered to obtain lightning attachment to UHV lines but LPM in its initial stage do not deal with the detailed physics of the upward leader inception, i.e., corona inception and unstable as well as stable upward leader inception from the object on the ground.
In this thesis a model for the lightning attachment has been developed based on the present knowledge of the lightning physics. The thesis mainly focuses on the modelling of upward leader inception and propagation for lightning attachment to UHV power trans-mission lines. Upward leader inception is modeled based on the corona charge present near the conductor region and the upward leader propagation model is based on the correlation between the lightning induced voltage on the conductor and the voltage drop along the upward leader channel. The present model considers corona inception and modelling of unstable and stable upward leader inception from the ground object for the analysis of the lightning attachment process.
The upward leader inception model developed is compared with the previous inception models and the results obtained using the present and previous models are found to be comparable. Lightning striking distances ( nal jump) for various lightning return stroke current were computed for di erent conductor heights using present lightning attachment model. It is seen that the striking distance increases with the increase in lightning re-turn stroke current and increases with increase in conductor heights. The striking distance computed using the present model matches with the value calculated using the equation proposed by the IEEE working group for the applicable conductor heights of up to 8 m.
The in uence of the conductor operating voltage, cloud electric eld, lightning down-ward leader lateral distance, conductor length, transmission line tower and conductor sag on the upward lightning leader inception are analysed and reported in the thesis. It is found that the lightning attraction to power transmission line increases with increase in conductor positive operating voltage and decreases with increase in conductor negative op-erating voltage. The presence of transmission line tower reduces the lightning attachment to the conductor lines and the probability of lightning strike decreases with the increase in downward leader lateral distance from the conductor lines.
The present lightning attachment model is applied to study the shielding failure of UHV power transmission lines rated for 1200 kV ac (delta and horizontal con guration) and for 800 kV dc (with and without a dedicated metallic return conductor) and thereby the lightning shielding failure ash-over rate is computed for the UHV power transmission lines. It is seen that the lightning shielding rate for UHV power transmission lines depend on the lateral distance of the downward leader channel, instantaneous 50 Hz voltage on the transmission line conductor, height of the transmission line conductor, induced voltages on the conductor and the lightning return stroke current.
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