Conferences related to Fuses

Back to Top

2018 18th International Workshop on Junction Technology (IWJT)

IWJT is an open forum focused on the needs and interest of the community of a junction formation technology in semiconductors.


2018 24th International Conference on Pattern Recognition (ICPR)

ICPR will be an international forum for discussions on recent advances in the fields of Pattern Recognition, Machine Learning and Computer Vision, and on applications of these technologies in various fields

  • 2016 23rd International Conference on Pattern Recognition (ICPR)

    ICPR'2016 will be an international forum for discussions on recent advances in the fields of Pattern Recognition, Machine Learning and Computer Vision, and on applications of these technologies in various fields.

  • 2014 22nd International Conference on Pattern Recognition (ICPR)

    ICPR 2014 will be an international forum for discussions on recent advances in the fields of Pattern Recognition; Machine Learning and Computer Vision; and on applications of these technologies in various fields.

  • 2012 21st International Conference on Pattern Recognition (ICPR)

    ICPR is the largest international conference which covers pattern recognition, computer vision, signal processing, and machine learning and their applications. This has been organized every two years by main sponsorship of IAPR, and has recently been with the technical sponsorship of IEEE-CS. The related research fields are also covered by many societies of IEEE including IEEE-CS, therefore the technical sponsorship of IEEE-CS will provide huge benefit to a lot of members of IEEE. Archiving into IEEE Xplore will also provide significant benefit to the all members of IEEE.

  • 2010 20th International Conference on Pattern Recognition (ICPR)

    ICPR 2010 will be an international forum for discussions on recent advances in the fields of Computer Vision; Pattern Recognition and Machine Learning; Signal, Speech, Image and Video Processing; Biometrics and Human Computer Interaction; Multimedia and Document Analysis, Processing and Retrieval; Medical Imaging and Visualization.

  • 2008 19th International Conferences on Pattern Recognition (ICPR)

    The ICPR 2008 will be an international forum for discussions on recent advances in the fields of Computer vision, Pattern recognition (theory, methods and algorithms), Image, speech and signal analysis, Multimedia and video analysis, Biometrics, Document analysis, and Bioinformatics and biomedical applications.

  • 2002 16th International Conference on Pattern Recognition


2018 25th IEEE International Conference on Image Processing (ICIP)

The International Conference on Image Processing (ICIP), sponsored by the IEEE Signal Processing Society, is the premier forum for the presentation of technological advances and research results in the fields of theoretical, experimental, and applied image and video processing. ICIP 2018, the 25th in the series that has been held annually since 1994, brings together leading engineers and scientists in image and video processing from around the world.


2018 26th Signal Processing and Communications Applications Conference (SIU)

The general scope of the conference ranges from signal and image processing to telecommunication, and applications of signal processing methods in biomedical and communication problems.

  • 2017 25th Signal Processing and Communications Applications Conference (SIU)

    Signal Processing and Communication Applications (SIU) conference is the most prominent scientific meeting on signal processing in Turkey bringing together researchers working in signal processing and communication fields. Topics include but are not limited to the areas of research listed in the keywords.

  • 2016 24th Signal Processing and Communication Application Conference (SIU)

    Signal Processing Theory, Statistical Signal Processing, Nonlinear Signal Processing, Adaptive Signal Processing, Array and Multichannel Signal Processing, Signal Processing for Sensor Networks, Time-Frequency Analysis, Speech / Voice Processing and Recognition, Computer Vision, Pattern Recognition, Machine Learning for Signal Processing, Human-Machine Interaction, Brain-Computer Interaction, Signal-Image Acquisition and Generation, image Processing, video Processing, Image Printing and Presentation, Image / Video / Audio browsing and retrieval, Image / Video / Audio Watermarking, Multimedia Signal Processing, Biomedical Signal Processing and Image Processing, Bioinformatics, Biometric Signal-Image Processing and Recognition, Signal Processing for Security and Defense, Signal and Image Processing for Remote Sensing, Signal Processing Hardware, Signal Processing Education, Radar Signal Processing, Communication Theory, Communication Networks, Wireless Communications

  • 2015 23th Signal Processing and Communications Applications Conference (SIU)

    Signal Processing Theory Statistical Signal Processing Nonlinear Signal Processing Adaptive Signal Processing Array and Multichannel Signal Processing Signal Processing for Sensor Networks Time-Frequency Analysis Speech / Voice Processing and Recognition Computer Vision Pattern Recognition Machine Learning for Signal Processing Human-Machine Interaction Brain-Computer Interaction Signal-Image Acquisition and Generation image Processing video Processing Image Printing and Presentation Image / Video / Audio browsing and retrieval Image / Video / Audio Watermarking Multimedia Signal Processing Biomedical Signal Processing and Image Processing Bioinformatics Biometric Signal-Image Processing and Recognition Signal Processing for Security and Defense Signal and Image Processing for Remote Sensing Signal Processing Hardware Signal Processing Education Radar Signal Processing Communication Theory Communication Networks Wireless Communications

  • 2014 22nd Signal Processing and Communications Applications Conference (SIU)

    SIU will be held in Trabzon, Turkey at the Karadeniz Technical University Convention and Exhibition Centre on April 23, 2014. SIU is the largest and most comprehensive technical conference focused on signal processing and its applications in Turkey. Last year there were 500 hundred participants. The conference will feature renowned speakers, tutorials, and thematic workshops. Topics include but are not limited to: Signal Procesing, Image Processing, Communication, Computer Vision, Machine Learning, Biomedical Signal Processing,

  • 2013 21st Signal Processing and Communications Applications Conference (SIU)

    Conference will discuss state of the art solutions and research results on existing and future DSP and telecommunication systems, applications, and related standardization activities. Conference will also include invited lectures, tutorials and special sessions.

  • 2012 20th Signal Processing and Communications Applications Conference (SIU)

    Conference will discuss state of the art solutions and research results on existing and future DSP and telecommunication systems, applications, and related standardization activities. Conference will also include invited lectures, tutorials and special sessions.

  • 2011 19th Signal Processing and Communications Applications Conference (SIU)

    Conference will bring together academia and industry professionals as well as students and researchers to present and discuss state of the art solutions and research results on existing and future DSP and telecommunication systems, applications, and related standardization activities. The Conference will also include invited lectures, tutorials and special sessions.

  • 2010 IEEE 18th Signal Processing and Communications Applications Conference (SIU)

    S1.Theory of Signal-Processing S2.Statistical Signal-Processing S3.Multimedia Signal-Processing S4.Biomedical Signal-Processing S5.Sensor Networks S6.Multirate Signal-Processing S7.Pattern Recognition S8.Computer Vision S9.Adaptive Filters S10.Image/Video/Speech Browsing, Retrieval S11.Speech/Audio Coding S12.Speech Processing S13.Human-Machine Interfaces S14.Surveillance Signal Processing S15.Bioinformatics S16.Self-Learning S17.Signal-Processing Education S18.Signal-Processing Systems S1

  • 2009 IEEE 17th Signal Processing and Communications Applications Conference (SIU)

    The scope of the conference is to cover recent topics in theory and applications of Signal Processing and Communications.

  • 2008 IEEE 16th Signal Processing and Communications Applications Conference (SIU)

    Signal Processing, Image Processing, Speech Processing, Pattern Recognition, Human Computer Interaction, Communication, Video and Speech indexing, Computer Vision, Biomedical Signal Processing

  • 2007 IEEE 15th Signal Processing and Communications Applications (SIU)

  • 2006 IEEE 14th Signal Processing and Communications Applications (SIU)

  • 2005 IEEE 13th Signal Processing and Communications Applications (SIU)

  • 2004 IEEE 12th Signal Processing and Communications Applications (SIU)


2018 40th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC)

The conference program will consist of plenary lectures, symposia, workshops and invitedsessions of the latest significant findings and developments in all the major fields of biomedical engineering.Submitted papers will be peer reviewed. Accepted high quality papers will be presented in oral and postersessions, will appear in the Conference Proceedings and will be indexed in PubMed/MEDLINE


More Conferences

Periodicals related to Fuses

Back to Top

Antennas and Propagation, IEEE Transactions on

Experimental and theoretical advances in antennas including design and development, and in the propagation of electromagnetic waves including scattering, diffraction and interaction with continuous media; and applications pertinent to antennas and propagation, such as remote sensing, applied optics, and millimeter and submillimeter wave techniques.


Audio, Speech, and Language Processing, IEEE Transactions on

Speech analysis, synthesis, coding speech recognition, speaker recognition, language modeling, speech production and perception, speech enhancement. In audio, transducers, room acoustics, active sound control, human audition, analysis/synthesis/coding of music, and consumer audio. (8) (IEEE Guide for Authors) The scope for the proposed transactions includes SPEECH PROCESSING - Transmission and storage of Speech signals; speech coding; speech enhancement and noise reduction; ...


Automation Science and Engineering, IEEE Transactions on

The IEEE Transactions on Automation Sciences and Engineering (T-ASE) publishes fundamental papers on Automation, emphasizing scientific results that advance efficiency, quality, productivity, and reliability. T-ASE encourages interdisciplinary approaches from computer science, control systems, electrical engineering, mathematics, mechanical engineering, operations research, and other fields. We welcome results relevant to industries such as agriculture, biotechnology, healthcare, home automation, maintenance, manufacturing, pharmaceuticals, retail, ...


Biomedical Circuits and Systems, IEEE Transactions on

The Transactions on Biomedical Circuits and Systems addresses areas at the crossroads of Circuits and Systems and Life Sciences. The main emphasis is on microelectronic issues in a wide range of applications found in life sciences, physical sciences and engineering. The primary goal of the journal is to bridge the unique scientific and technical activities of the Circuits and Systems ...


Biomedical Engineering, IEEE Transactions on

Broad coverage of concepts and methods of the physical and engineering sciences applied in biology and medicine, ranging from formalized mathematical theory through experimental science and technological development to practical clinical applications.


More Periodicals


Xplore Articles related to Fuses

Back to Top

Coordination of inverse-time overcurrent relays with fuses using genetic algorithm

[{u'author_order': 1, u'affiliation': u'Departamento de Ciências Exatas e Tecnológicas Universidade Estadual de Santa Cruz Ilhéus-BA, Brasil', u'full_name': u'Vin\xedcius Souza Madureira'}, {u'author_order': 2, u'affiliation': u'Departamento de Ciências Exatas e Tecnológicas Universidade Estadual de Santa Cruz Ilhéus-BA, Brasil', u'full_name': u'Thiago Correia Vieira'}] 2018 Simposio Brasileiro de Sistemas Eletricos (SBSE), None

This work presents a methodology to obtain discrete adjustments for overcurrent relays and fuse selection using Genetic Algorithm. The purpose is to minimize the protection devices time and therefore reduce the impact caused by short circuits in an electrical installation. In addition, the mathematical formulation presented aims to ensure that the resulting protection system is coordinated and selective. The choice ...


Fatigue life prediction model for surface mountable power electronics fuses

[{u'author_order': 1, u'affiliation': u'Electronics Division, Eaton Corporation, Pleasanton, USA', u'full_name': u'Ramdev Kanapady'}, {u'author_order': 2, u'affiliation': u'Electronics Division, Eaton Corporation, Pleasanton, USA', u'full_name': u'Tissaphern Mirfakhrai'}, {u'author_order': 3, u'affiliation': u'Electronics Division, Eaton Corporation, Pleasanton, USA', u'full_name': u'Clarita Knoll'}, {u'author_order': 4, u'affiliation': u'Electronics Division, Eaton Corporation, Pleasanton, USA', u'full_name': u'Zhuomin Liu'}] 2018 IEEE Applied Power Electronics Conference and Exposition (APEC), None

In this paper, a multi-physics based fatigue life prediction model for surface mountable power electronics fuses is presented. It is aimed at a realistic, simple and accurate model development conducted through pulse cycling. Fatigue is the dominating failure mechanism of fuse links and enhancing their cycle life is a major concern for power electronics designers and users. To reduce development ...


Why the operation failure of high breaking capacity fuses is so frequent?

[{u'author_order': 1, u'affiliation': u'Electrical and Electronics Department, Engineering School, Rio Cuarto National University, Rio Cuarto, Argentina', u'full_name': u'Juan C. G\xf3mez'}, {u'author_order': 2, u'affiliation': u'Electrical and Electronics Department, Engineering School, Rio Cuarto National University, Rio Cuarto, Argentina', u'full_name': u'Daniel H. Tourn'}, {u'author_order': 3, u'affiliation': u'Electrical and Electronics Department, Engineering School, Rio Cuarto National University, Rio Cuarto, Argentina', u'full_name': u'Sebasti\xe1n Nesci'}, {u'author_order': 4, u'affiliation': u'Electrical and Electronics Department, Engineering School, Rio Cuarto National University, Rio Cuarto, Argentina', u'full_name': u'Leonardo Sanchez'}, {u'author_order': 5, u'affiliation': u'Electrical and Electronics Department, Engineering School, Rio Cuarto National University, Rio Cuarto, Argentina', u'full_name': u'Hern\xe1n Rovere'}] CIRED - Open Access Proceedings Journal, 2017

High breaking capacity (HBC) fuse is today one of the most used low- and medium-voltage protective devices. Its operation principle presents two singular current values of difficult interruption, 'critical current' and 'minimum breaking current.' These fuses, in general are not able to break any current that begins the melting process. An introduction about the HBC fuse design characteristics and operation ...


IEEE Standard Design Tests for High-Voltage (>1000 V) Fuses and Accessories Corrigenda 1

None IEEE Std C37.41-2016/Cor 1-2017 (Corrigenda to IEEE Std C37.41-2016), 2018

Corrigenda concerning required procedures for performing design tests for high-voltage fuses are specified. These design tests, are appropriate to expulsion fuses, and cover interrupting tests and fuses using polymeric insulators.


IEEE Standard Specifications for High-Voltage (>1000 V) Fuses and Accessories

None IEEE Std C37.42-2016 - Redline, 2017

Specifications for high voltage (above 1000 volts) Class A and Class B expulsion and current-limiting fuses. This includes: a) Expulsion type Class A [distribution class] fuses, fuse cutouts, fuse disconnecting switches, their associated fuse links or refill units, disconnecting cutouts, and accessories for these devices with rated voltages from 1 through 38 kV. b) Expulsion type Class B [power class] ...


More Xplore Articles

Educational Resources on Fuses

Back to Top

eLearning

No eLearning Articles are currently tagged "Fuses"

IEEE-USA E-Books

  • Circuit Breakers, Reclosers, Switches, and Fuses

  • Circuit Breakers, Reclosers, Switches, and Fuses

  • Electrical System

    This chapter discusses the basic design and components of an electrical distribution system. In the design and operation of the electrical system of a power plant, the reliability of the electrical system is critical to the safe and reliable operation of the power plant. National Electrical Safety Code (NESC) requires that all circuit conductors have protection systems to protect the conductors against excessive heating by overcurrent, alarm, indication, or trip devices with the exception of conductors that are normally grounded. In addition to the system modes of operation, the load development schedule should include items such as peak load requirements, temporary power requirements and installation timing requirements. Electrical equipment enclosures are designed and built for various types of operating environments. Busway is a common name applied to equipment utilized for the transfer of large amounts of electrical energy in a reliable method between two locations.

  • Protective Device Selection And Coordination

    The X/R ratio at the point of a short-circuit fault determines the degree of asymmetry and the rate of decay of the short circuit current waveform. Protective devices are designed for a specific X/R ratio so a realistic interrupting current magnitude can be determined and used as a design criterion for the device. The most common devices to interrupt fault current are fuses and circuit breakers. Different technologies exist for arc extinction in fuses. Fused low-voltage power circuit breakers are rated based on first-cycle symmetrical current per the IEEE C37 standards. Molded-case circuit breakers are commonly used to protect low-voltage circuits. Distribution current-limiting fuses are typically filled with sand to absorb the thermal energy produced by the arc that forms as the fusible element melts. Factors such as predamage, tolerances, ambient temperature, and preloading can affect the operating time of a fuse.

  • Lightning and Surge Protection

    Surge voltages are a significant hazard in power transmission and distribution systems. Surges are the causes of much equipment failure, such as downed conductors, fires, and step and touch potentials, which may injure people nearby. The design manufacture and installation of electrical power equipment and systems must be fundamentally based on safety both for users of the equipment and for those who operate and maintain it. Opening of circuit breakers on capacitors may produce overvoltages resulting in restrike. The restrike is caused by the voltage across the opening contacts to exceed the breakdown voltage of the gap. The resulting transient can reach three times the peak voltage. The temporary overvoltage (TOV) rating should be greater than or equal to the maximum line-to-ground voltage during a single-line to ground fault (SLGF).

  • An Adaptive Relaying Scheme for Fuse Saving

    In some situations, utilities may try to ?>save?> the fuse of a circuit following temporary faults by de-energizing the line with the fast operation of an upstream recloser before the fuse is damaged. This fuse saving practice is accomplished through proper time coordination between a recloser and a fuse. However, installation of microgrid distributed generation (DG) into distribution networks may affect this coordination due to additional fault current contribution from the distributed resources. This phenomenon of recloser-fuse miscoordination is investigated in this chapter with the help of a typical network that employs fuse saving. Limitations of a recloser equipped with time and instantaneous overcurrent elements in respect of fuse saving in the presence of DG is discussed. An adaptive relaying strategy is proposed to ensure fuse saving in the new scenario even in the worst fault conditions. The simulation results obtained by adaptively changing relay settings in response to changing DG configuration confirm that the settings selected theoretically in accordance with the proposed strategy hold well in operation1.

  • PHM in Healthcare

    This chapter introduces the trend of healthcare in the United States, and discusses unique features of healthcare devices and specific safety priorities, as well as clinical priorities related to the devices. It describes benefits of prognostics and health management (PHM) and summarizes the need for PHM in the healthcare devices. The chapter discusses considerations of healthcare devices ‐ such as implantable devices and care bots ‐ with the explanation of unique features of the devices. Unlike engineering venues where PHM is used on installed equipment or complex electronic systems, with implantable medical devices, data collection often occurs where "in situ" is consistent with "surgically embedded inside a patient". The use of fuses and canaries for PHM presents unanswered questions. Enhanced PHM capabilities will allow detection of failures, avoid catastrophic failures, and prevent damage within the human body as well as for the medical devices.

  • System Protection

    There are two types of "protection" referred to in electric power systems. The first is system protection having to do with protective relays, fault currents, effective grounding, circuit breakers, fuses, etc. The second is personal protection having to do with rubber gloves, insulating blankets, grounding jumpers, switching platforms, tagging, etc. This chapter discusses the first one "system protection". System protection protects power system equipment from damage due to power faults and/or lightning strikes. Distribution lines are normally fed radially out of substations, meaning distribution feeders have only one utility source. Transmission protection is much different than distribution protection simply because transmission is usually not radially fed. Normally transmission systems have multiple feeds to a substation and transmission lines must have special protective relaying schemes to identify the actual faulted transmission line. The purpose of a synchronizing relay is to safely connect two 3¿¿¿phase lines together or to place a spinning generator online.

  • Switchgear and Motor Control Centers

    In industrial environments, electricity is provided to loads from load centers, including switchgear and motor control centers (MCCs). Both of these load centers are having hinged doors for easy internal access. Smaller electrical components can be housed in enclosures that are classified by NEMA Type, which defines the ability of the enclosure to resist environmental factors. Several important ratings apply to both switchgear and MCCs. A continuous current rating limits the temperature rise of the load center components, particularly the insulation. A short-circuit current rating determines both the interrupting capability of the circuit breakers and fuses, and the mechanical strength of the bracing and support systems. Arc flash hazard must be addressed to determine safe working procedures around energized equipment. NFPA standard 70E and IEEE standard 1584 address the arc flash hazard by providing guidance for performing calculations to determine the incident energy during an arc flash event.

  • Effects of High Fault Currents on Circuit Breakers

    This chapter examines some of the causes of circuit breaker failure. It also analyzes some of the factory testing procedures which help to ensure safe design and manufacture of circuit breakers. The most eminent reason for utilities to maintain or even reduce their fault current levels is to ensure proper functioning of circuit-interrupting devices such as circuit breakers and fuses. Circuit breakers in the United States are rated by the American National Standards Institute (ANSI) and the Institute of Electrical and Electronics Engineers (IEEE). While current-limiting fuses are enclosed in a sealed cylinder, and are usually contained in a metal-enclosed switchgear, limiting the danger even if their short-circuit rating is exceeded, expulsion fuse links are mounted in open tubes on utility poles. The chapter presents case studies that describe the replacement of air-magnetic circuit breakers whose interrupting ratings have been exceeded with new SF6 or vacuum interrupters.



Standards related to Fuses

Back to Top

IEEE Application Guide for Low-Voltage AC Power Circuit Breakers Applied with Separately-Mounted Current-Limiting Fuses

This guide applies to low-voltage ac power circuit breakers of the 635 V maximum voltage class with separately-mounted current-limiting fuses for use on ac circuits with available short-circuit currents of 200 000 A (rms symmetrical) or less. Low-voltage ac fused power circuit breakers and combinations of fuses and molded-case circuit breakers are not covered by this guide. This guide sets ...


IEEE Guide for the Application, Operation, and Maintenance of High-Voltage Fuses, Distribution Enclosed Single-Pole Air Switches, Fuse Disconnecting Switches, and Accessories

Document is a guide to the application, operation and Maintenance of all types of High-Voltage fuses and associated equipment covered by the C37.4X series of standards. The project will revise approximately 20% of the document, while retaining the origional document scope. [Original Scope - Revise/update scope, make improvements, and expand application to cover other devices (specifically full-range fuses, capacitor fuses, ...


IEEE Standard Design Tests for High-Voltage (>1000 V) Fuses, Fuse and Disconnecting Cutouts, Distribution Enclosed Single-pole Air Switches, Fuse Disconnecting Switches, and Fuse Links and Accessories Used with These Devices


IEEE Standard for Low-Voltage AC Power Circuit Breakers Used in Enclosures

The scope of this standard includes the following enclosed low-voltage ac power circuit breakers: a) Stationary or drawout type of two-, three-, or four-pole construction with one or more rated maximum voltages of 635 V (600 V for units incorporating fuses), 508 V, and 254 V for application on systems having nominal voltages of 600 V, 480 V, and 240 ...


IEEE Standard for Low-Voltage AC Power Circuit Protectors Used in Enclosures


More Standards

Jobs related to Fuses

Back to Top