SU1430868A1 - Eddy-current transducer for flaw detection - Google Patents

Abstract

The invention relates to non-destructive testing and can be used for the inspection of flat electrically conducting objects, as well as hollow electrically conducting objects from their inner surface. The transducer's sensitivity to defects is increased by the fact that the 4Td conductor is made in the form of a massive ring 4, to which U-shaped jumper 5 connected to the diametrically opposite parts is connected to a closed magnetic conductor 1 and placed symmetrically relative to the massive ring, and the measuring winding 6 is coaxial with a massive ring 4. In the process of control, by means of a closed magnetic circuit 1, an alternating current is generated, which flows through the U-shaped bridge 5 and the massive ring 4. In this case The currents flowing in diametrically opposite parts of the massive ring have a different direction. As a result, the transducer appears to be balanced, since the measuring winding is coupled with the same flows in the opposite direction. When interacting with continuity defects, the equality of magnetic fluxes is violated, and the resulting voltage on the measuring winding depends on the parameters of the defect. 3 ZP .. f-ly, 2 ill. u (L 4; ii with about 00 and 00 riv.)

Description

The invention relates to non-destructive testing and can be used for the inspection of flat electrically conducting objects, as well as hollow electrically conducting objects from their inner surface.

The purpose of the invention is to increase the sensitivity of the transducer to defects, which is achieved by creating an exciting system with multidirectional magnetic fluxes.

FIG. 1 shows the eddy current transducer design} in FIG. 2 - the same, top view.

The eddy current transducer consists of a closed magnetic conductor 1 with a supply winding 2, a conductor 3 formed by a massive ring 4 and a U-shaped jumper 5 coupled to a closed magnetic conductor 1 and placed symmetrically with respect to the massive ring 4, as well as a measuring winding 6 placed with massive ring 4. To improve the manufacturability of the eddy current transducer U-shaped terminal 5, it is recommended to install it with a removable upper strap 7 fastened with screws 8 and 9.

For flaw detection of the inner surface of hollow cylindrical objects, the measuring winding 6 is recommended to be placed on the end of a massive

rings, and the outer diameter of the measuring winding 6 to choose the same with the outer diameter of the massive ring 4

G.

For flaw detection of flat objects, the working end of the massive ring 4 and the working end of the measuring winding 6 are recommended to be placed in one plane (the invoice version of the converter).

In order to increase the balancing level of the eddy current transducer, the measuring winding 6 is recommended to be made in the form of two differentially connected sections. In this case, in the pass-through version of the converter, the sections of the measuring winding are located in one plane and have a different number of turns. The ratio of the number of turns in the sections is determined by the balancing conditions. In an overhead embodiment, the transducer of the measuring section of the coil can be arranged both in one plane and in parallel planes. In the simplest case

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five

0 5 o

five

0

0

five

the measuring winding section 6 is directly wound onto its inner section.

In addition, in order to increase the balancing equation, the measuring winding 6 is recommended to be rotatable with respect to the massive ring 4.

The eddy current transducer works as follows.

The winding 2 is powered by an alternating voltage generator (not shown) and creates a magnetic flux that closes in a closed magnetic conductor 1. Since the magnetic conductor 1 is inductively coupled to the U-shaped jumper 5 of the conductor 3, in the latter there is a current flowing through P -shaped bridge 5 and the massive ring 4. In this case, the currents flowing in diametrically opposite parts of the massive ring 4 have a different direction. Because of this, the resulting flux linkage of the magnetic flux created by the current flowing through the conduit 3, with the turns of the measuring winding 6, is close to zero. However, due to the incomplete symmetry of the flux linkage distribution, a certain level of converter unbalance is inevitable. This level can be increased by completing the measuring winding 6 with two sections, as indicated above, and also by rotating the measuring winding 6 relative to the massive ring. In the latter case, the circumstance that the turns of the measuring winding 6 actually have some sum eccentricity, obtained by winding its conductors, is used. Therefore, when the measuring winding 6 rotates, the total flux linkage varies smoothly within insignificant limits, which is required for balancing.

Balanced in this way, the transducer is brought into electromagnetic interaction with the object being monitored.

Claims (4)

1. Eddy current transducer for flaw detection, containing a closed magnetic circuit with a supply winding, a measuring winding and a conductor in the form of an electrically closed loop, inductively coupled to the supply winding, characterized in that, in order to increase the sensitivity, the conductor is designed as a massive ring, diametrically opposite parts of which a U-shaped jumper is attached, coupled to a closed magnetic circuit, and the measuring winding is located coaxially with a massive ring. 2. A transducer according to claim 1, characterized in that, in order to increase the sensitivity during the inspection of hollow cylindrical objects from their inner surface, the measuring winding is placed on the end of the massive ring and has the same outer diameter about it. I 3. The Converter in PP. 1 and 2, characterized in that, in order to increase the sensitivity during flaw detection of flat objects, the workers-ends of the massive ring and the measuring winding are placed in one plane. 4. Converter in PP. 1 and 3, characterized in that, for the purpose of balancing, the measuring winding is adapted to rotate relative to a massive ring cf3US.2