SU616576A1 - Stuck-on eddy-current transducer - Google Patents

Description

I. The invention relates to the field of non-destructive testing using the eddy current method and can be used in tracking systems for the gap between the surface of an object and a converter — or for measuring TOL. Of dielectric coatings on an electrically conductive base. Known overhead eddy current transducer containing coaxial excitation and measuring inductance coils used in systems following the gap | l .. However, it does not have the necessary noise immunity, since the magnitudes of its signal depends not only on the size of the gap, but also on the defects of the control volume. The closest to the technical essence of the invention is an invoice eddy current transducer containing exciting and measuring inductors, lying in orthogonal planes x 2. However, even this converter does not possess the required noise immunity, since it is very susceptible to possible defects in the object of control. The purpose of the invention is to increase the noise immunity of the converter when the gap between the converter and the surface of the test object changes. This is achieved by the fact that the converter is provided with a second excitation inductance coil located in the same plane with the first, and both excitation coils are arranged symmetrically relative to the plane of the measuring coil. In addition, the sections of the turns of the exciting coils facing each other, are parallel. The measuring coil is made in the form of a rectangle, long, the sides of which are parallel to the plane of the exciting coils. The drawing shows the proposed overlay eddy current transducer. The converter consists of exciting 1.2 and measuring 3 coils located in orthogonal planes. Measuring. the coil 3 is rectangular in shape, and the exciting coils are located symmetrically with respect to the plane of the measuring coil, and the sections of the turns facing each other are parallel. eh works as follows.

An alternating current is passed through the excitation coils 2 and 3 so that its direction is the same for the parts of the turns of the coils facing each other. Then, the transducer is installed on a controlled surface with a predetermined gap value and it is judged on further changes of this gap by changing the transducer signal. . .

The increase in noise immunity of the proposed converter is due to the fact that, due to the presence of a second excitation winding, the eddy currents spread so that in the region of their greatest electromagnetic interaction with the measuring coil, the eddy current channels are parallel to the plane of the measuring catuips. It can be shown that in this case the deformation of the eddy current contour leads to the smallest change in the mutual induction between this circuit and the measuring coil.

Thus, the noise immunity of the converter is increased, since in the presence of a defect its signals change to a much lesser extent.

Claims (3)

1. Invoice eddy current transducer for non-destructive testing containing the exciting and measuring coils inductance, lying in orthogonal planes, which means that, in order to increase the noise immunity of the converter when the gap between the converter and the surface of the counter object changes, it is equipped with a second exciting inductor inductance, located in the same plane with: the first, and both exciting coils are placed symmetrically relative to the plane of the measuring coil. 2. The transducer pop.1 about t - ly h and y with and with the fact that the sections of the turns of the exciting coils facing each other, are parallel. 3. Converter on PP. 1 and 2, characterized in that the measuring coil is made in the form of a rectangle, the long sides of which are parallel to the plane exciting the Katuyuka. Sources of information taken into account in the examination: 1.Shkarlet Yu.M. An instrument for controlling the thickness of metal products using a tracking system. Proceedings of MEI, vyp.57, M., 1964, p. 135-146. 2. Handbook of Nondestructive control of metals and products. Ed. Samoilovich GS, M., Mechanical Engineering, 1976, P.206.