Conferences related to Static Electricity

Back to Top

2020 IEEE International Conference on Plasma Science (ICOPS)

IEEE International Conference on Plasma Science (ICOPS) is an annual conference coordinated by the Plasma Science and Application Committee (PSAC) of the IEEE Nuclear & Plasma Sciences Society.


2019 21st European Conference on Power Electronics and Applications (EPE '19 ECCE Europe)

Energy conversion and conditioning technologies, power electronics, adjustable speed drives and their applications, power electronics for smarter grid, energy efficiency,technologies for sustainable energy systems, converters and power supplies


2019 41st Annual International Conference of the IEEE Engineering in Medicine & Biology Society (EMBC)

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


2019 IEEE 28th International Symposium on Industrial Electronics (ISIE)

The conference will provide a forum for discussions and presentations of advancements inknowledge, new methods and technologies relevant to industrial electronics, along with their applications and future developments.


2019 IEEE 58th Conference on Decision and Control (CDC)

The CDC is recognized as the premier scientific and engineering conference dedicated to the advancement of the theory and practice of systems and control. The CDC annually brings together an international community of researchers and practitioners in the field of automatic control to discuss new research results, perspectives on future developments, and innovative applications relevant to decision making, systems and control, and related areas.The 58th CDC will feature contributed and invited papers, as well as workshops and may include tutorial sessions.The IEEE CDC is hosted by the IEEE Control Systems Society (CSS) in cooperation with the Society for Industrial and Applied Mathematics (SIAM), the Institute for Operations Research and the Management Sciences (INFORMS), the Japanese Society for Instrument and Control Engineers (SICE), and the European Union Control Association (EUCA).


More Conferences

Periodicals related to Static Electricity

Back to Top

Antennas and Wireless Propagation Letters, IEEE

IEEE Antennas and Wireless Propagation Letters (AWP Letters) will be devoted to the rapid electronic publication of short manuscripts in the technical areas of Antennas and Wireless Propagation.


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.


Computational Biology and Bioinformatics, IEEE/ACM Transactions on

Specific topics of interest include, but are not limited to, sequence analysis, comparison and alignment methods; motif, gene and signal recognition; molecular evolution; phylogenetics and phylogenomics; determination or prediction of the structure of RNA and Protein in two and three dimensions; DNA twisting and folding; gene expression and gene regulatory networks; deduction of metabolic pathways; micro-array design and analysis; proteomics; ...


Control Systems Technology, IEEE Transactions on

Serves as a compendium for papers on the technological advances in control engineering and as an archival publication which will bridge the gap between theory and practice. Papers will highlight the latest knowledge, exploratory developments, and practical applications in all aspects of the technology needed to implement control systems from analysis and design through simulation and hardware.


Energy Conversion, IEEE Transaction on

Research, development, design, application, construction, installation, and operation of electric power generating facilities (along with their conventional, nuclear, or renewable sources) for the safe, reliable, and economic generation of electrical energy for general industrial, commercial, public, and domestic consumption, and electromechanical energy conversion for the use of electrical energy


More Periodicals

Most published Xplore authors for Static Electricity

Back to Top

Xplore Articles related to Static Electricity

Back to Top

Measurement of static electricity generated by human walking

Proceedings of SICE Annual Conference 2010, 2010

Electrical charge phenomena often cause problems in our daily lives. For example, static electricity that builds up in the human body can cause pain when it discharges. Since static electricity is not visible to, it is difficult to detect and prevent its discharge. In this paper, we describe a newly developed static electricity sensor and its performance in our experiments. ...


Development of 2V sensitivity static electricity sensor with vertically mounted large electrode

2016 IEEE SENSORS, 2016

This paper reports a very high sensitivity static electricity sensor assembled with a vertically mounted large area electrode. The electrode is fabricated by perforation of single crystalline silicon, and automatically aligned on an electrostatic actuator stage. The sensor measures a charged voltage of measuring object surface using a 4×4 mm2electrode driven at the resonant frequency in vertical direction to the ...


Measurement technique of vibrational distribution using static electricity and capacitance

2015 IEEE International Symposium on Inertial Sensors and Systems (ISISS) Proceedings, 2015

We propose a noncontact vibrational distribution measurement technique using static electricity and a capacitance sensor array. A vibrating object was intentionally charged, and a time-varying electric field was induced in this study. The vibrational amplitude and frequency of the object were measured by detecting a change in the capacitance between the object and a sensor. The sensor used for detection ...


Laboratory Facility to Study Static Electricity Phenomenon

2018 XIV International Scientific-Technical Conference on Actual Problems of Electronics Instrument Engineering (APEIE), 2018

Static electricity phenomenon as well as causes of its occurrence and all related issues emerging at the electrical energy objects are considered in the article. The presented laboratory facility allows the students to gain practical skills to study the phenomenon while learning the subject "Electromagnetic compatibility in electrical energy".


Electric shock injuries from static electricity discharges

2011 IEEE IAS Electrical Safety Workshop, 2011

Most people are aware of electrostatic discharges (ESD) at two extremes - the annoying shock from static accumulation from sliding across an automobile seat or shuffling across a carpet, and the highly dangerous and destructive energy discharge in lightning strikes. Between these two extremes are static discharges from manufacturing operations that can cause shock injuries. Hazards of static electricity in ...


More Xplore Articles

Educational Resources on Static Electricity

Back to Top

IEEE-USA E-Books

  • Measurement of static electricity generated by human walking

    Electrical charge phenomena often cause problems in our daily lives. For example, static electricity that builds up in the human body can cause pain when it discharges. Since static electricity is not visible to, it is difficult to detect and prevent its discharge. In this paper, we describe a newly developed static electricity sensor and its performance in our experiments. The static electricity charged when walking is synchronized with the walking steps. The static electricity was openly detected by a bioelectric amplifier. We attempted to use the change in output voltage in synchronization with walking as a walking step counter as well as walking form checker. Here, as a basic study, we investigate the relationship between the feet and the floor.

  • Development of 2V sensitivity static electricity sensor with vertically mounted large electrode

    This paper reports a very high sensitivity static electricity sensor assembled with a vertically mounted large area electrode. The electrode is fabricated by perforation of single crystalline silicon, and automatically aligned on an electrostatic actuator stage. The sensor measures a charged voltage of measuring object surface using a 4×4 mm2electrode driven at the resonant frequency in vertical direction to the object surface. The charged voltage of surface is in proportion to the alternative current caused by change of capacitance existing between the electrode and surface. Realized resolution of static electricity was 1.96V, and it is about 100 times higher performance than the previously reported MEMS static electricity sensor.

  • Measurement technique of vibrational distribution using static electricity and capacitance

    We propose a noncontact vibrational distribution measurement technique using static electricity and a capacitance sensor array. A vibrating object was intentionally charged, and a time-varying electric field was induced in this study. The vibrational amplitude and frequency of the object were measured by detecting a change in the capacitance between the object and a sensor. The sensor used for detection comprises a parallel plate of sensors of diameter Φ1 mm. The vibrational distribution over an area of 25 mm × 25 mm with an amplitude of 100 μm was measured in 1 s by simultaneously processing the detected signal using a capacitance sensor array.

  • Laboratory Facility to Study Static Electricity Phenomenon

    Static electricity phenomenon as well as causes of its occurrence and all related issues emerging at the electrical energy objects are considered in the article. The presented laboratory facility allows the students to gain practical skills to study the phenomenon while learning the subject "Electromagnetic compatibility in electrical energy".

  • Electric shock injuries from static electricity discharges

    Most people are aware of electrostatic discharges (ESD) at two extremes - the annoying shock from static accumulation from sliding across an automobile seat or shuffling across a carpet, and the highly dangerous and destructive energy discharge in lightning strikes. Between these two extremes are static discharges from manufacturing operations that can cause shock injuries. Hazards of static electricity in industrial and manufacturing operations are generally viewed as a potential ignition source in flammable and explosive environments, or destructive to semiconductor electronic devices, but not as a source for shock injury. Measures to control the static electricity shock hazard and safeguard people are not addressed in the most visible and applied standards addressing electrical safety in the workplace. This paper describes manufacturing and other industrial scenarios in which the potential for injury from static electricity discharges exist, and discuss methods to prevent, control, and protect personnel from injury.

  • Prevention Is Better Than a Cure: Electric Shock Injuries from Static Electricity Discharges

    Most people are aware of electrostatic discharges at two extremes: 1) the annoying shock from static accumulation from sliding across an automobile seat or shuffling across a carpet and 2) the highly dangerous and destructive energy discharge in lightning strikes. Between these two extremes are the static discharges from manufacturing operations that can cause shock injuries. Hazards of static electricity in industrial and manufacturing operations are generally viewed as a potential ignition source in flammable and explosive environments, or destructive to semiconductor electronic devices, but not as a source for shock injury, Measures to control the static electricity shock hazard and safeguard people are not addressed in the most visible and applied standards addressing electrical safety in the workplace. This article describes manufacturing and other industrial scenarios in which the potential for injury from static electricity discharges exist and discusses methods to prevent, control, and protect personnel from injury.

  • Static electricity-friend or foe

    Static electricity is a potential ignition source in hazardous areas. This paper introduces a systematic approach to identifying hazards attributable to static electricity. It explains how and where static electricity is generated, and gives guidance on how to control its effects and reduce the risk of ignition. The topics covered include: flammable atmospheres; charge generation; charge accumulation in liquids, isolated conductors, high resistivity solid items and insulating sheets; and electrostatic discharges including spark, corona, brush, cone and lightning discharges.<<ETX>>

  • Investigation of static electricity and optical retardation generation with different rubbing fabric on liquid crystal display device

    We have studied the static electricity and optical retardation generated by rubbing the surfaces of polyimide (PI) and polyamide (PA). The static electricity increases with the rubbing strength (RS) and varies with the different PI surfaces. We also investigated how the differences in the rubbing fabric affects the magnitude of the induced static electricity; the order of this effect is nylon>rayon>cotton. The induced static electricity is not only directly related to the values of the specific resistivity of the rubbed PI films, but also the RS and the ability of the rubbing fabric to generate and add a static electric charge. The order of the optical retardation produced by the rubbing fabric on rubbed PI surfaces is nylon>rayon>cotton, coinciding with the order of the generated static electricity.

  • Design of diesel engine exhaust three-stage particulate-trap and noise-silence system based on centrifugal and static electricity technologies

    This paper introduced a development of a diesel engine exhaust three-stage particulate-trap and noise-silence system based on centrifugal and static electricity technologies. This system separated particulate material from the exhaust stream by means of centrifugal that was formed through rotating exhaust stream and static electricity that was formed by a static electricity- generating unit, make it burned out by a infrared heater. Authors had designed a centrifugal and static electricity soot particulate trap device, the soot burning device and burning control device, and installed it on the engine frame and tested it. The results showed satisfactory effectiveness cleaning and silencing is achieved simultaneously.

  • Induction heating power CCL static electricity coupling load matching analysis

    In this paper CCL static electricity coupling load matching method using in induction heating power is described. The characteristics of CCL resonant circuit and output maximum power is discussed in detail. Under the condition of output rated load power, give the current and voltage peculiarity curves for different parameters. Finally give the calculation of matching component Lp, C and Cs. Because CCL static electricity coupling load matching method could calculate the complementary capacitance easily at the time of output maximum power, another thought of induction heating load matching is put forward to use in the future.



Standards related to Static Electricity

Back to Top

Standard for Padmounted Type, Self-Cooled, Single Phase Distribution Transformers; High Voltage, 34500 GrdY/19920 Volts and below, Low voltage, 240/120 Volts; 167 kVA and smaller

This standard covers certain electrical, dimensional, mechanical characteristics and safety requirements of single-phase, 60 HZ, liquid filled, self-cooled, padmounted, compartmental-type distribution transformers. These transformers are rated 167 kVA and smaller, with the high voltages of 34 500 GrdY/19 920 volts and below for operation between one phase and grounded neutral, and low voltage of 240/120 volts. These transformers are generally ...



Jobs related to Static Electricity

Back to Top