Advanced magnetic-field-measuring device built

A new type of vibrating sample magnetometer (VSM) was designed for measuring the magnetic properties of soft and hard magnetic materials is described. The developed instrument differs from the traditional Foner type because in our system the motion of the specimen is parallel with the lines of the external magnetic field. Therefore, this instrument can be called parallel motion vibrating sample magnetometer (PMVSM). The special vibrating system contains a vibrating rod which holds the specimen. This arrangement can make the sample replacement and positioning fast and convenient. Because of the versatility of the PMVSM instrument it could be a useful measuring device for materials science laboratory and educational purposes as well.

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MEASUREMENT AND MODELLING OF GRADIENT MAGNETIC FIELDS FOR BIO-CHEMICAL SEPARATION PROCESSES

International Journal of Engineering Science Technologies ◽

10.29121/ijoest.v5.i2.2021.174 ◽

2021 ◽

Vol 5 (2) ◽

pp. 69-80

Author(s):

Hatice Bilgili ◽

Teymuraz Abbasov ◽

Yusuf Baran

Keyword(s):

Magnetic Field ◽

Magnetic Fields ◽

Field Gradient ◽

Permanent Magnets ◽

Magnetic Field Gradient ◽

Chemical Separation ◽

Submicron Particles ◽

Separation Processes ◽

Measuring Device ◽

The Magnetic Field

Separation processes are widely used in chemical and biotechnical processes. Especially biomagnetic separation is an important issue among effective separation processes to separate the magnetic micron and submicron particles. It is necessary to establish and determine a high magnetic field or field gradient in the separation cell. However, it is not easy to determine the magnetic field gradient in the working region for different separation in practice. The reason for these difficulties is that the magnetic cells used in biochemical separation have different geometries and there are no simple and useful systems to easily measure these magnetic fields. Two main objectives are aimed in this study. First, a simple measuring device design can measure gradient magnetic fields with high precision of about 0,01mm and, secondly, obtain simple empirical expressions for the magnetic field. A magnetometer with Hall probes that works with the 3D printer principle was designed and tested to measure the magnetic field. Magnetic field changes were measured according to the surface coordinates on the measurement platform or measuring cell. Numerous experimental measurements of gradient magnetic fields generated by permanent magnets have been taken. The results obtained from the studies and results from the proposed empirical models were compared.

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Interpretation of magnetic resonance measurements in the varying earth’s magnetic field

Geophysics ◽

10.1190/geo2015-0474.1 ◽

2016 ◽

Vol 81 (4) ◽

pp. WB23-WB31 ◽

Cited By ~ 12

Author(s):

Anatoly Legchenko ◽

Jean-Michel Vouillamoz ◽

Fabrice Messan Amene Lawson ◽

Christian Alle ◽

Marc Descloitres ◽

...

Keyword(s):

Magnetic Field ◽

Magnetic Resonance ◽

Synthetic Data ◽

Test Site ◽

Complex Problem ◽

Nonlinear Inversion ◽

Earth’S Magnetic Field ◽

Measuring Device ◽

Magnetic Resonance Sounding ◽

Earth's Magnetic Field

At the scale of a magnetic resonance sounding (MRS) field setup, the earth’s magnetic field in the subsurface may vary laterally with depth and over time. These variations can be caused by different natural factors and generally cannot be compensated for by accurate tuning of the measuring device. The varying geomagnetic field (GMF) causes nonresonance conditions of excitation that affect the amplitude and phase of the MRS signal. Usually, variations of the GMF do not exceed a few hertz and their effect on the amplitude is relatively small, permitting us to assume near-resonance conditions for inversion. However, in some cases, the results may be erroneous if a varying GMF is not taken into account. Motivated by possible improvements in MRS inversion, we have developed a procedure for measuring and interpreting MRS data that considers a varying GMF. Our results showed that it is relatively easy to take a time-varying GMF into account. As a demonstration, we have developed the inversion of MRS data measured in Benin (West Africa). A depth-varying GMF is a more complex problem, and to consider this, we have developed an algorithm of nonlinear inversion. We have tested this approach on synthetic data, which resulted in an improved inversion. Field validation of this procedure awaits the discovery of a suitable test site with known variations of the earth’s magnetic field in the subsurface.

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Measurement of Helmholtz Coil

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.738-739.893 ◽

2015 ◽

Vol 738-739 ◽

pp. 893-898

Author(s):

Jun Feng Zhu ◽

Xin Yan ◽

Ling Ling Zhou ◽

Xiao Xin Zhao

Keyword(s):

Magnetic Field ◽

Uniform Magnetic Field ◽

Helmholtz Coil ◽

Basic Principles ◽

Circle Center ◽

Coil Axis ◽

Coordinate Origin ◽

Field Measuring ◽

Field Lines ◽

The Magnetic Field

Based on the basic principles of electromagnetism, the application of Shanghai Fudan-day Welcomes UNESCO Instruments Ltd. THQHC-1 type Helmholtz coil magnetic field measuring instrument for measuring coil uniform magnetic field generates a magnetic field on the carrier to get round the coil axis, online circle center at (coordinate origin) at the maximum magnetic field strength. Starting from the coordinate origin, to the sides, the magnetic field lines accelerate the decline, when the distance exceeds the coil radius, the decelerating decline. Conclusions for the understanding of a uniform magnetic field reference.

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