Universal Magnetoresistive Current Sensor Ppt
Chemical Technology, Control and Management
Article Title
Output of the sensor. The magnetoresistive element responds with a robust 3-4% change in bias current. The practical magnetic field strength required to operate a magnetoresistive sensor can be as low as 15 Gauss. Giant Magnetoresistive Sensors (GMR) The latest magnetic field sensing technology is called giant magnetoresistive (GMR). Many application of GMR sensor, such as: current sensor, linear and rotational position sensor, head recording, and biosensor, are reviewed. Benefits of Magnetic Sensors 34. The Universal Current Sensor T he measurement of electric current strength is not always easy, especially when the measured signal requires further electronic conditioning. Simply connecting an ammeter to an electrical circuit and reading out the value is no longer enough. The current signal must be fed into a computer in which sensors.
Authors
Abstract
In communication and communication devices, power equipment, relay protection and automation terminals, in the electric power industry of 'smart' cities and homes, in industry, in railway transport, microprocessor-based relay protection and automation devices, distributed generation installations, including renewable energy sources, and electricity storage, as well as 'intelligent' automated information and measurement systems are beginning to be used. Contactless converters of direct and alternating currents of control and control systems are widely used in them. Their disadvantages are a narrow range of controlled currents, large dimensions and weight. Therefore, it is important to eliminate them. The paper discusses the general principles of construction of contactless converters of large direct currents, the main requirements for them, and shows the results of the development of one of the options proposed by us, universal contactless magneto-modulation converters of large direct currents with an extended range for various control and control systems. They differ from the known ones by an extended controlled range with small dimensions and weight, and increased accuracy and sensitivity. The converter has a simple and technological design with low material consumption and cost, and can control large direct currents, as well as alternating currents, without contact. The paper considers the errors from external magnetic fields of universal contactless converters of control and control systems. It is shown that the error from the external magnetic field does not exceed 0.08% if the number of sections of the measuring winding is even and with their symmetrical arrangement, and with their even increase-the error decreases. At the same time, the developed contactless converters can be widely used in industry, metallurgy, railway transport, agriculture, water and farming, as well as in the electric power industry of “smart” cities and homes and for checking electric meters at the place of their installation.
First Page
47
Last Page
55
DOI
https://doi.org/10.51346/tstu-02.21.1-77-0007
Universal Magnetoresistive Current Sensor Ppt Download
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Voltage Sensor
Recommended Citation
Plakhtiev, A.M; Gaziev, Gayratjon; Meliboyev, Yahyojon; and Doniyorov, Odil (2021) 'ERRORS OF UNIVERSAL CONTACTLESS CONVERTERS OF MONITORING AND CONTROL SYSTEMS FROM EXTERNAL MAGNETIC FIELDS,' Chemical Technology, Control and Management: Vol. 2021 : Iss. 2 , Article 7.
DOI: https://doi.org/10.51346/tstu-02.21.1-77-0007
Available at: https://uzjournals.edu.uz/ijctcm/vol2021/iss2/7
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