Conferences related to Surge Protective Devices - c62

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2020 IEEE Power & Energy Society General Meeting (PESGM)

The Annual IEEE PES General Meeting will bring together over 2900 attendees for technical sessions, administrative sessions, super sessions, poster sessions, student programs, awards ceremonies, committee meetings, tutorials and more


2020 IEEE/PES Transmission and Distribution Conference and Exposition (T&D)

Bi-Annual IEEE PES T&D conference. Largest T&D conference in North America.


2019 IEEE Milan PowerTech

PowerTech is the IEEE PES anchor conference in Europe and has been attended by hundreds of delegates from around the world. It will be an international forum with programme for individuals working in industry and academia, to network, exchange ideas, and discuss the results of their research and development work.

  • 2003 Bologna Power Tech

  • 2005 IEEE Russia Power Tech

  • 2007 IEEE Power Tech

  • 2009 IEEE Bucharest Power Tech

    PowerTech is the anchor conference of the IEEE-PES in Europe. It is intended to provide a forum for scientists and engineers interested in electric power engineering to share ideas, results of their scientific work, to learn from each other as well as to establish new friendships and rekindle existing ones.

  • 2011 IEEE Trondheim PowerTech

    PowerTech is the anchor conference of the IEEE Power & Energy Society in Europe. It is intended to provide a forum for electric power engineering scientists and engineers to share ideas, results of their scientific work and to learn from each other.

  • 2013 IEEE Grenoble PowerTech

    PowerTech is the anchor conference of the IEEE Power & Energy Society in Europe. It is intended to provide a forum for electric power engineering scientists and engineers to share ideas, results of their scientific work, to learn from each other as well as to establish new friendships and maintain existing ones.

  • 2015 IEEE Eindhoven PowerTech

    This conference will continue the tradition of the PowerTech conferences held in odd years in Athens, Stockholm, Budapest, Porto, Bologna, St. Petersburg, Lausanne, Bucharest, Trondheim and Grenoble.PowerTech is the anchor conference of the IEEE Power Engineering Society in Europe. It is intended to provide a forum, in the European geographical area, for scientists and engineers interested in electric power engineering to exchange ideas, results of their scientific work, to learn from each other as well as to establish new friendships and rekindle existing ones. Student participation in Power Tech provides an important ingredient toward the event’s success: a special award, the Basil Papadias Award, is presented to the author of the best student paper at each edition. The Power Engineering Society of IEEE organized similar conferences in other parts of the world, such as PowerCon, in the Asia-Pacific region.

  • 2017 IEEE Manchester PowerTech

    this is IEEE PES anchor conference in Europe covering all areas of electrical power engineering


2019 IEEE Industry Applications Society Annual Meeting

The Annual Meeting is a gathering of experts who work and conduct research in the industrial applications of electrical systems.


2018 53rd International Universities Power Engineering Conference (UPEC)

UPEC is a long-established international conference which provides a major forum for scientists, young researchers, PhD students and engineers worldwide to present, review and discuss the latest developments in Electrical Power Engineering and relevant technologies including energy storage and renewables

  • 2004 International Universities Power Engineering Conference (UPEC)

  • 2006 International Universities Power Engineering Conference (UPEC)

  • 2007 Universities Power Engineering Conference (UPEC)

  • 2008 43rd International Universities Power Engineering Conference (UPEC)

    Its aim will be to provide a professional forum for engineers and research scientists from the universities, consultants, and in the manufacturing and supply industries opportunities to present their work and explore potential trends and recent developments, current practices in Power Engineering and related fields.

  • 2009 44th International Universities Power Engineering Conference (UPEC)

    UPEC has been long-established as a major annual international forum for the presentation, discussion and exchange of information concerning new trends in all areas of electric power engineering. Contributions from younger engineers and researchers are particularly encouraged at UPEC, where ideas can be aired freely and new relationships developed.

  • 2010 45th International Universities Power Engineering Conference (UPEC)

    The global energy challenge, the ageing of electrical networks in industrial countries, and the extension of the grids in developing countries require significant research effort and the need for talented engineers and innovators is critical to the electrical energy industry. UPEC is an ideal forum to address such issues, and to network and meet experts in these areas

  • 2012 47th International Universities Power Engineering Conference (UPEC)

    A major international forum for the presentation, discussion and exchange of information concerning new trends in electrical power engineering. To become better informed about the latest developments in the field of power engineering.

  • 2013 48th Universities' Power Engineering Conference (UPEC)

    The conference provides a major international focus for the presentation, discussion and exchange of information concerning new trends in Electrical Power Engineering. The conference is very popular with young researchers, PhD students and engineers from the electrical power industry. Given the major challenges now facing the electrical power industry, and the energy sector in general, this conference provides an ideal opportunity to address some of these challenges.

  • 2014 49th International Universities Power Engineering Conference (UPEC)

    Given the major challenges now facing the electrical power industry, and the energy sector in general, this conference provides an ideal opportunity to address some of these challenges. It also provides the opportunity to network and to meet the experts in these areas.

  • 2015 50th International Universities Power Engineering Conference (UPEC)

    The conference provides a major international focus for the presentation, discussion and exchange of information concerning new trends in Electrical Power Engineering. The conference is very popular with young researchers, PhD students and engineers from the electrical power industry. Given the major challenges now facing the electrical power industry, and the energy sector in general, this conference provides an ideal opportunity to address some of these challenges.

  • 2016 51st International Universities Power Engineering Conference (UPEC)

    UPEC is a long-established conference, which is very popular with young researchers, PhD students and engineers from the electrical power industry. The aim of the conference is to allow participants to exchange experiences and discuss the most up-to-date topics in Power Engineering. The global energy challenge, the ageing of electrical networks in industrial countries, and the extension of the grid systems in developing countries require significant research input in the area. UPEC is an ideal forum to address some of these issues, and to network and meet with talented engineers and innovators in these areas.



Periodicals related to Surge Protective Devices - c62

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Dielectrics and Electrical Insulation, IEEE Transactions on

Electrical insulation common to the design and construction of components and equipment for use in electric and electronic circuits and distribution systems at all frequencies.


Electromagnetic Compatibility, IEEE Transactions on

EMC standards; measurement technology; undesired sources; cable/grounding; filters/shielding; equipment EMC; systems EMC; antennas and propagation; spectrum utilization; electromagnetic pulses; lightning; radiation hazards; and Walsh functions


Electron Device Letters, IEEE

Publishes original and significant contributions relating to the theory, design, performance and reliability of electron devices, including optoelectronic devices, nanoscale devices, solid-state devices, integrated electronic devices, energy sources, power devices, displays, sensors, electro-mechanical devices, quantum devices and electron tubes.


Industry Applications, IEEE Transactions on

The development and application of electric systems, apparatus, devices, and controls to the processes and equipment of industry and commerce; the promotion of safe, reliable, and economic installations; the encouragement of energy conservation; the creation of voluntary engineering standards and recommended practices.


Power Delivery, IEEE Transactions on

Research, development, design, application, construction, the installation and operation of apparatus, equipment, structures, materials, and systems for the safe, reliable, and economic delivery and control of electric energy for general industrial, commercial, public, and domestic consumption.



Most published Xplore authors for Surge Protective Devices - c62

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Xplore Articles related to Surge Protective Devices - c62

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Electronic systems protection via advanced surge protective devices

Conference Record of the 2002 IEEE Industry Applications Conference. 37th IAS Annual Meeting (Cat. No.02CH37344), 2002

Market demand and manufacturer innovations have led to improved surge protective device (SPD) design and features. New fusing techniques and advancements in metal oxide varistors (MOVs) provide a more comprehensive design, which results in a safer and more reliable SPD that improves overall system integrity. Adding new integral thermal protection in series with individually fused MOVs provides protection against low ...


Surge Protection Of Cable-Connected Equipment On Higher-Voltage Distribution Systems

1979 7th IEEE/PES Transmission and Distribution Conference and Exposition, 1979

Since the 1969 presentation on protection of cable-connected distribution equipment, 15 kV and below, the working group has studied systems of 25 kV and 34.5 kV voltage class. Considerable information on field experience has been gathered. Analytical and experimental work has been done on the determination of attenuation of surges in cables. Various protection methods have been discussed and laboratory ...


Energy coordination of ZnO varistor based SPDs in surge current due to direct lightning flashes

2014 International Conference on Lightning Protection (ICLP), 2014

Surge protective devices (SPDs) play an important role to protect the valuable electrical and electronic equipment against transients originating from lightning. Class I tested SPDs are needed to divert surge currents due to direct lightning flashes. In order to achieve the effective protection of sensitive electrical and electronic systems, coordinated SPD systems should be designed and installed. This paper presents ...


Surge protection of automatic transfer switches — Application note

2014 IEEE PES General Meeting | Conference & Exposition, 2014

Given the emphasis on reliability of facilities and backup power systems, this paper provides application guidance on the use of surge protective devices for automatic transfer switches for low voltage ac circuits. This paper is intended to be used as a supplement to the direction provided in IEEE Std C62.72TM-2007, IEEE Guide for the Application of Surge-Protective Devices for Low-Voltage ...


Bibliography Relevant to Surge Voltage Protection of Ac Rotating Machinery

IEEE Power Engineering Review, 2001

Prepared by Working Group 3.4.9, "Guide for the Application of Surge Voltage Protective Equipment on AC Rotating Machinery 1000 Volts and Greater." The working group scope is to investigate past and present publications and practices in the application of surge voltage protection to ac rotating machinery; integrate and consolidate the knowledge on the subject; and prepare a suitable industry guide ...



Educational Resources on Surge Protective Devices - c62

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IEEE.tv Videos

EMBC 2011-Workshop- Biological Micro Electro Mechanical Systems (BioMEMS): Fundamentals and Applications-Ali Khademhosseini
Shao-Chuan Lee: SandUSB: An Installation-Free Sandbox for USB Peripherals: WF-IoT 2016
EMBC 2011-Workshop- Biological Micro Electro Mechanical Systems (BioMEMS): Fundamentals and Applications-Utkan Demirci
EMBC 2011-Workshop- Biological Micro Electro Mechanical Systems (BioMEMS): Fundamentals and Applications-Mehmet R. Dokmeci
EMBC 2011-Workshop-Biological Micro Electro Mechanical Systems (BioMEMS): Fundamentals and Applications-Michelle Khine
Some Recent Work in Computational Intelligence for Software Engineering
SCV SSIT Chapter Meeting, July 8, 2020, Ethics and Covid-19
IMS 2011 Microapps - Volume Manufacturing Trends for Automotive Radar Devices
Analog Devices SP4T RF MEMS Switch with Integrated Driver Circuitry for RF Instrumentation: MicroApps 2015 - Analog Devices
IEEE Life Sciences: Wearable Medical Devices Advancing bioengineering
Prototyping MIMO Systems with the AD9361: MicroApps 2015 - Analog Devices
802.19: Wireless Coexistence
Radiated Performance Assessment of Wireless Communications Devices - An Operator's Perspective
EDA Challenges in Designing Computing Systems with postCMOS Devices - IEEE Rebooting Computing 2017
A Unified Hardware/Software Co-Design Framework for Neuromorphic Computing Devices and Applications - IEEE Rebooting Computing 2017
APEC 2015: KeyTalks - How to Optimize Performance and Reliability of GaN Power Devices
802.15: Wireless Personal Area Network
IMS 2012 Special Sessions: The Evolution of Some Key Active and Passive Microwave Components - E. C. Niehenke
Evaluating Over-The-Air Performance of MIMO Wireless Devices
Mobile Internet Devices at Intel

IEEE-USA E-Books

  • Electronic systems protection via advanced surge protective devices

    Market demand and manufacturer innovations have led to improved surge protective device (SPD) design and features. New fusing techniques and advancements in metal oxide varistors (MOVs) provide a more comprehensive design, which results in a safer and more reliable SPD that improves overall system integrity. Adding new integral thermal protection in series with individually fused MOVs provides protection against low fault current (high impedance fault), while preserving high surge current protection. When applied using IEEE's recommended cascaded approach for coordinated, facility-wide protection, integrated SPDs offer the best solution for a safe and reliable surge suppression system.

  • Surge Protection Of Cable-Connected Equipment On Higher-Voltage Distribution Systems

    Since the 1969 presentation on protection of cable-connected distribution equipment, 15 kV and below, the working group has studied systems of 25 kV and 34.5 kV voltage class. Considerable information on field experience has been gathered. Analytical and experimental work has been done on the determination of attenuation of surges in cables. Various protection methods have been discussed and laboratory tests and analyses performed. The working group concludes that for the BIL's being used with the higher distribution voltages, protection can be provided with an arrester at the overhead line-cable junction only, with some limitations, for 25 kV class, 125 kV BIL systems. For 34.5 kV systems with 125 kV or 150 kV BIL, other protection methods must be considered.

  • Energy coordination of ZnO varistor based SPDs in surge current due to direct lightning flashes

    Surge protective devices (SPDs) play an important role to protect the valuable electrical and electronic equipment against transients originating from lightning. Class I tested SPDs are needed to divert surge currents due to direct lightning flashes. In order to achieve the effective protection of sensitive electrical and electronic systems, coordinated SPD systems should be designed and installed. This paper presents the experimental results obtained from the actual installation conditions of SPDs with the aims to understand the energy sharing of the cascaded Class I and II SPDs and to propose the effective selection and installation methods of SPDs. The residual voltage of each SPD and energy coordination between the upstream Class I tested SPD and the downstream Class tested II SPD were measured using a 10/350 μs current wave.

  • Surge protection of automatic transfer switches — Application note

    Given the emphasis on reliability of facilities and backup power systems, this paper provides application guidance on the use of surge protective devices for automatic transfer switches for low voltage ac circuits. This paper is intended to be used as a supplement to the direction provided in IEEE Std C62.72TM-2007, IEEE Guide for the Application of Surge-Protective Devices for Low-Voltage (1000 V or Less) AC Power Circuits.

  • Bibliography Relevant to Surge Voltage Protection of Ac Rotating Machinery

    Prepared by Working Group 3.4.9, "Guide for the Application of Surge Voltage Protective Equipment on AC Rotating Machinery 1000 Volts and Greater." The working group scope is to investigate past and present publications and practices in the application of surge voltage protection to ac rotating machinery; integrate and consolidate the knowledge on the subject; and prepare a suitable industry guide for the application of protective devices in the protection of ac rotating machinery against surge voltages, including integrally connected components. The bibliography organization is alphabetic by author, within reverse chronological decades.

  • Power-Quality Investigation of Surge Protective Device Failures During Open Transition for a Wastewater Treatment Facility

    To date, many papers have been written about various concepts in power system grounding, explaining the application, advantages, and disadvantages of each of the solidly grounded, resistance-grounded, and ungrounded systems. The purpose of this paper is not to explain the theory behind the aforementioned concepts but rather substantiate them with actual field measurements during a failure of a surge protective device. The measurements taken, utilizing digital power-quality monitors, and subsequent analysis will demonstrate the adverse effect of arcing ground faults on ungrounded systems as system voltages escalate to undesirable values. This paper will then examine high- resistance grounding as a superior solution from a service-continuity perspective with a beneficial dampening effect on high-voltage transients that exist on ungrounded systems during arcing ground faults. Consequently, this paper will discuss the operational precautions that the end user must be aware of before proceeding with the implementation of a high-resistance-grounding scheme.

  • Hybrid Integrated Surge Protector for Digital Switching System

    A newly developed hybrid integrated surge protector (HISP) is described. The HISP circuit configuration employs a three-stage protection circuit. The HISP consists of thick film resistors whose pattern and trimming configuration are designed to enable resistance stability for the surge current to be obtained and newly developed ieadless surge protective devices, such as a three- electrode gas-filled protector, a threeelectrode ZnO varistor, and appliqued fusible resistor. After reliability evaluation testing, the HISP and its component Parts are proved to satisfy system requirements and provisions for practical use. Its Size is one-third and its cost will be one-half of that for a discrete component protector.

  • Surge protection of low voltage AC drives — Application note

    Given the emphasis on reliability of facilities and ac motor drives, this paper provides application guidance on the use of surge protective devices with motor drives on low voltage ac circuits. This paper is intended to be used as a supplement to the direction provided in IEEE Std C62.72TM-2007, IEEE Guide for the Application of Surge-Protective Devices for Low-Voltage (1000 V or Less) AC Power Circuits.

  • High demands on cellular networks-High demands on Surge Protective Devices

    The continuous utilisability of transmitting/receiving systems and switching centres for mobile communications important. These influence the domain of private telecommunication directly by customer satisfaction, in the domain of professional mobile radio (PMR; e.g. public safety organisations), the continuous availability is in the foreground. With increased expansion and due to the high danger potential lightning protection and thus over voltage protection is becoming more relevant for cost-intensive engineering and the demand for permanent availability of the network operation are making surge protective devices (SPD) indispensable. The performance of such SPD has to fulfil the highest requirements. For use in cellular networks a lot of different mechanical and physical requirements are in demand. A combination of class I arresters, based on spark gap technology and class II arresters, based on MOV technology realise a protective device which combine a high absorption of energy and a fast response. This paper describes the requirements, which has to be fulfilled to realise an effective internal lightning protection system

  • Application of Metal-Oxide-Varistor Surge Arresters on Distribution Systems

    The emergence of the metal-oxide varistor (MOV) has made a significant impact on station-class surge arrester technology. Areas in which MOV arresters will provide superior protection on distribution systems are examined even though the current discharge voltage characteristics of MOV arresters are the same as those of conventional surge arresters. Areas discussed include .Severe switching areas (capacitor banks); .High temporary overvoltage areas; .Underground and overhead systems.



Standards related to Surge Protective Devices - c62

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errata


Guide for the Application of Component Surge-Protective Devices for Use in Low-Voltage [Equal to Or Less Than 1000 V (ac) Or 1200 V (dc)] Circuits

This guide covers the application of air gap, gas tube, metal oxide varistor, and avalanche junction semiconductor components used in surge protective devices, equipment, or systems involving low-voltage power, data, communications and signaling circuits. This guide is intended to be used with, or to complement, related documents IEEE C62.31, C62.32, C62.33 and C62.35.


IEEE Guide for the Application of Surge Protective Devices for Low Voltage (1000 Volts or Less) AC Power Circuits

The transient overvoltages or surge events that are described and discussed in this guide are those that originate outside of a building or facility and impinge on a power distribution system (PDS) through the service entrance conductors. Transient overvoltages or surge events that originate from equipment within a specific facility are not within the scope of this document. This guide ...


IEEE Guide for the Application of Surge Protectors Used in Low-Voltage (Equal to or Less than 1000 Vrms or 1200 Vdc) Data, Communications, and Signaling Circuits

This guide applies to surge protectors used in balanced or unbalanced data, communication and signaling circuits with voltages equal to or less than 1000Vrms or 1200 Vdc. The surge protectors covered are multiple-component series or parallel combinations of linear or non-linear elements, packaged for the purpose of limiting voltage, current, or both. This guide is intended to complement the IEEE ...


IEEE Guide for the Application of Surge Voltage Protective Equipment on AC Rotating Machinery 1000 Volts and Greater

This guide covers the application of surge voltage protective equipment to AC rotating machines rated 1000 volts and greater. The guide does not cover motors applied in solid-state switched adjustable speed drives. Part 1 covers the insulation surge withstand strength of motors and generators with windings having form-wound multi-turn coils and the application of surge protection to form-wound multi-turn coil ...