Conferences related to Maximum Winding Temperature

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2021 IEEE Photovoltaic Specialists Conference (PVSC)

Photovoltaic materials, devices, systems and related science and technology


2020 IEEE 18th International Conference on Industrial Informatics (INDIN)

INDIN focuses on recent developments, deployments, technology trends, and research results in Industrial Informatics-related fields from both industry and academia


2020 IEEE Applied Power Electronics Conference and Exposition (APEC)

APEC focuses on the practical and applied aspects of the power electronics business. Not just a power designer’s conference, APEC has something of interest for anyone involved in power electronics including:- Equipment OEMs that use power supplies and converters in their equipment- Designers of power supplies, dc-dc converters, motor drives, uninterruptable power supplies, inverters and any other power electronic circuits, equipments and systems- Manufacturers and suppliers of components and assemblies used in power electronics- Manufacturing, quality and test engineers involved with power electronics equipment- Marketing, sales and anyone involved in the business of power electronic- Compliance engineers testing and qualifying power electronics equipment or equipment that uses power electronics


2020 IEEE IAS Petroleum and Chemical Industry Committee (PCIC)

The PCIC provides an international forum for the exchange of electrical applications technology related to the petroleum and chemical industry. The PCIC annual conference is rotated across North American locations of industry strength to attract national and international participation. User, manufacturer, consultant, and contractor participation is encouraged to strengthen the conference technical base. Success of the PCIC is built upon high quality papers, individual recognition, valued standards activities, mentoring, tutorials, networking and conference sites that appeal to all.


2020 IEEE International Symposium on Circuits and Systems (ISCAS)

The International Symposium on Circuits and Systems (ISCAS) is the flagship conference of the IEEE Circuits and Systems (CAS) Society and the world’s premier networking and exchange forum for researchers in the highly active fields of theory, design and implementation of circuits and systems. ISCAS2020 focuses on the deployment of CASS knowledge towards Society Grand Challenges and highlights the strong foundation in methodology and the integration of multidisciplinary approaches which are the distinctive features of CAS contributions. The worldwide CAS community is exploiting such CASS knowledge to change the way in which devices and circuits are understood, optimized, and leveraged in a variety of systems and applications.


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Periodicals related to Maximum Winding Temperature

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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.


Applied Superconductivity, IEEE Transactions on

Contains articles on the applications and other relevant technology. Electronic applications include analog and digital circuits employing thin films and active devices such as Josephson junctions. Power applications include magnet design as well asmotors, generators, and power transmission


Components and Packaging Technologies, IEEE Transactions on

Component parts, hybrid microelectronics, materials, packaging techniques, and manufacturing technology.


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.


Electrical and Computer Engineering, Canadian Journal of

The Canadian Journal of Electrical and Computer Engineering, issued quarterly, has been publishing high-quality refereed scientific papers in all areas of electrical and computer engineering since 1976. Sponsored by IEEE Canada (The Institute of Electrical and Electronics Engineers, Inc., Canada) as a part of its role to provide scientific and professional activity for its members in Canada, the CJECE complements ...


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Most published Xplore authors for Maximum Winding Temperature

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Xplore Articles related to Maximum Winding Temperature

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IEEE Guide for Determination of Maximum Winding-Temperature Rise in Liquid Immersed Transformers -- Amendment 1

IEEE Std 1538a-2015 (Amendment to IEEE Std 1538-2000), 2015

The clause that addresses direct measurement with fiber-optic detectors is expanded and an annex detailing examples of installation techniques for fiber- optic probes is added in this amendment.


IEEE Approved Draft Guide for Determination of Maximum Winding Temperature Rise in Liquid Transformers Amendment#1

IEEE P1538a/D5, July 2015, 2015

This amendment expands the clause that addresses direct measurement with fiber optic detectors and adds an annex detailing examples of installation techniques for fiber optic probes. References are also updated.


IEEE Draft Guide for Determination of Maximum Winding Temperature Rise in Liquid Transformers Amendment#1

IEEE P1538a/D3, February 2015, 2015

This amendment expands the clause that addresses direct measurement with fiber optic detectors and adds an annex detailing examples of installation techniques for fiber optic probes. References are also updated.


IEEE Draft Guide for Determination of Maximum Winding Temperature Rise in Liquid Transformers Amendment#1

IEEE P1538a/D4, February 2015, 2015

This amendment expands the clause that addresses direct measurement with fiber optic detectors and adds an annex detailing examples of installation techniques for fiber optic probes. References are also updated.


IEEE Guide for Determination of Maximum Winding Temperature Rise in Liquid-Filled Transformers

IEEE Std 1538-2000, 2000

Provides guidance for determining the hottest-spot temperature in distribution and power transformers built in accordance with IEEE Std C57.12.00-2000. Describes the important criteriato be evaluated by any thermal model that can accurately predict the hottest-spot temperature in atransformer. Provides guidance for performing temperature-rise tests with direct measurement ofthe hottest-spot temperatures, and explains the importance of developing an accurate thermal model ...


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Educational Resources on Maximum Winding Temperature

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IEEE.tv Videos

MIRAI Program and the New Super-high Field NMR Initiative in Japan - Applied Superconductivity Conference 2018
IMS 2014: A 600 GHz Low-Noise Amplifier Module
CES 2008: Herman Miller's C2 Climate Control for the desktop
IMS 2012 Microapps - Reducing Active Device Temperature Rise and RF Heating Effects with High Thermal Conductivity Low Loss Circuit Laminates
30 Years to High Temperature Superconductivity (HTS): Status and Perspectives
AlGaN/GaN Plasmonic Terahertz Detectors
A Low Power High Performance PLL with Temperature Compensated VCO in 65nm CMOS: RFIC Interactive Forum
ISEC 2013 Special Gordon Donaldson Session: Remembering Gordon Donaldson - 7 of 7 - SQUID-based noise thermometers for sub-Kelvin thermometry
"Approximation- Beyond the Tyranny of Digital Computing," (Rebooting Computing)
A Precision 140MHz Relaxation Oscillator in 40nm CMOS with 28ppm/C Frequency Stability for Automotive SoC Applications: RFIC Interactive Forum 2017
IEEE Authoring Part 4: Paper Structure
Analog to Digital Traits
Advances on Many-objective Evolutionary Optimization - IEEE WCCI 2012
ASC-2014 SQUIDs 50th Anniversary: 1 of 6 Arnold Silver
High Frequency Magnetic Circuit Design for Power Electronics
A 28GHz CMOS Direct Conversion Transceiver with Packaged Antenna Arrays for 5G Cellular Systems: RFIC Industry Showcase 2017
IMS 2014:Active 600GHz Frequency Multiplier-by-Six S-MMICs for Submillimeter-Wave Generation
APEC 2011- Methode Electronics at APEC 2011
Interaction of ferromagnetic and superconducting permanent magnets - superconducting levitation
High-current HTS cables for magnet applications - ASC-2014 Plenary series - 8 of 13 - Thursday 2014/8/14

IEEE-USA E-Books

  • IEEE Guide for Determination of Maximum Winding-Temperature Rise in Liquid Immersed Transformers -- Amendment 1

    The clause that addresses direct measurement with fiber-optic detectors is expanded and an annex detailing examples of installation techniques for fiber- optic probes is added in this amendment.

  • IEEE Approved Draft Guide for Determination of Maximum Winding Temperature Rise in Liquid Transformers Amendment#1

    This amendment expands the clause that addresses direct measurement with fiber optic detectors and adds an annex detailing examples of installation techniques for fiber optic probes. References are also updated.

  • IEEE Draft Guide for Determination of Maximum Winding Temperature Rise in Liquid Transformers Amendment#1

    This amendment expands the clause that addresses direct measurement with fiber optic detectors and adds an annex detailing examples of installation techniques for fiber optic probes. References are also updated.

  • IEEE Draft Guide for Determination of Maximum Winding Temperature Rise in Liquid Transformers Amendment#1

    This amendment expands the clause that addresses direct measurement with fiber optic detectors and adds an annex detailing examples of installation techniques for fiber optic probes. References are also updated.

  • IEEE Guide for Determination of Maximum Winding Temperature Rise in Liquid-Filled Transformers

    Provides guidance for determining the hottest-spot temperature in distribution and power transformers built in accordance with IEEE Std C57.12.00-2000. Describes the important criteriato be evaluated by any thermal model that can accurately predict the hottest-spot temperature in atransformer. Provides guidance for performing temperature-rise tests with direct measurement ofthe hottest-spot temperatures, and explains the importance of developing an accurate thermal model to properly locate the temperature sensors.

  • A statistical approach of temperature calculation in electrical machines

    The thermal behavior of electrical machines is studied. The finite element method is used to calculate the magnetic field and temperature distribution inside the machine. The conductors are randomly distributed inside the slots using the Monte-Carlo method. The random distribution of the maximum temperature of the windings is calculated and its limits of confidence are evaluated.

  • Advanced Cooling Methods for High-Speed Electrical Machines

    High-speed electrical machines are gaining increasing attention, as they enable higher power densities in several applications such as micromachining spindles and turbo compressors. This brings along an important challenge in thermal management due to the higher loss densities in the machine. Therefore, a careful thermal analysis is required along with the electromagnetic and mechanical considerations during the design phase of the machines. In this paper, different forced cooling options are compared for a slotless-type high- speed permanent-magnet machine. Fast, yet sufficiently accurate thermal models are derived for analyzing these cooling concepts. This enables their coupling with electromagnetic models and incorporation into the machine optimization procedure, which would not be feasible when using computationally very intensive methods such as three-dimensional finite element method or computational fluid dynamics. The developed thermal models are first verified on mechanically simplified stator designs (in which no rotor coupling is possible), and later on fully functional high-speed electrical machine prototypes. Using an integrated cooling method instead of a standard cooling jacket, the power density can be nearly doubled while keeping the maximum winding temperature below 80 °C, without altering the rotor or the stator core geometries.

  • Energy efficiency assessment for inverter-fed induction motors

    This paper addresses the technical issues in the energy efficiency assessment for inverter-fed motor drives according to the international technical standard (TS) IEC 60034-23:2013. The critical points on the TS procedure are investigated by means of experimental results, with special emphasis on the influence of the DC bus voltage, the thermal aspects, the dead-times influence and compensation on the measurements suggested by the TS. For an easier fulfilment of the thermal constraints on the maximum winding temperature variation during the test, imposed by the Norm, a very simple thermal network is proposed. The model is also useful to evaluate the time duration of the experiment. The results of the experimental activity performed on two different induction motors are included in the paper.

  • Temperature prediction on power transformers and the guide on load dispatch

    Transformer winding temperature is a function of the load current and ambient temperature. As the maximum winding temperature at steady state operation is limited by IEEE/IEC standards, the higher the ambient temperature, the lower the permitted current. When the high temperature warning forecast from government climatological stations is available, the maximal load can be pre- calculated and, if necessary, the extra load can be pre-shifted to other transformers. This can help the dispatchers of power grid to prearrange the load in the power network from the 3-day to 7-day weather forecast of the climatological stations. This paper used the Finite Element approach to calculate the electrical-thermal-fluid dynamic phenomena in the power transformer. The results gave the relationship between winding temperature, load current, and the ambient temperature. A four dimension interpolation method is employed to give a good prediction of the power station temperature from the data of the climatological stations around. The four dimensions used include the longitude, the latitude, the altitude, and the time of the power stations and the climatological stations, respectively. The final results are discussed and possible applications are presented.

  • Quenching of multisection superconducting magnets and internal and external shunt resistors

    Self-protection of superconducting magnets by subdivision using internal and external shunt resistors was investigated. Temperature rise at various points of the winding was measured by means of thermocouples soldered to the conductor. The velocity of the normal-zone propagation along radial and axial directions was obtained. Initial current was varied from 0.3 to 0.9I/sub q/=1000 A. The effectiveness of protection by subdivision with external shunts depended on the number and dimensions of sections. It increased with decreasing single section size. When placed in the magnet, shunts work as a heater and diminish the quenching time and maximum winding temperature.<<ETX>>



Standards related to Maximum Winding Temperature

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IEEE Guide for Determination of Maximum Winding Temperature Rise in Liquid-Filled Transformers

Produce a guide for developing mathematical models and test procedures to determine the steady state maximum (hottest spot) and average winding temperature rise over ambient for liquid immersed distribution, power, network, and regulating transformers manufactured in accordance with IEEE C57.12.00.


IEEE Guide for Determination of Maximum Winding Temperature Rise in Liquid-Filled Transformers

Produce a guide for developing mathematical models and test procedures to determine the steady state maximum (hottest spot) and average winding temperature rise over ambient for liquid immersed distribution, power, network, and regulating transformers manufactured in accordance with IEEE C57.12.00.


IEEE Guide for Loading Dry-Type Distribution and Power Transformers

Update the existing document to resolve negative ballots received during re-affirmation and to include a section incorporating transformers with solid cast and/or resin encapsulated epoxy windings.


IEEE Guide for Loading Mineral-Oil-Immersed Power Transformers Up to and Including 100 MVA with 55 C or 65 C Average Winding Rise


IEEE Standard for Calculating the Current-Temperature of Bare Overhead Conductors

The purpose of this standard is to present a method of calculating the current-temperature relationship of bare overhead conductors. Conductor surface temperatures are a function of the following: a) Conductor material properties b) Conductor diameter c) Conductor surface conditions d) Ambient weather conditions e) Conductor electrical current The first two of these properties are specific chemical and physical properties. The ...



Jobs related to Maximum Winding Temperature

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