DE102008027525A1 - Eddy-current probe for e.g. layer thickness measurement at object, has coil body carrying excitation coil and measuring coil, where excitation coil and measuring coil include common electrical ground connection - Google Patents

Abstract

The probe has an excitation coil (1) for generating a magnetic field at a location of an object (O) to be measured, where the excitation coil is connected to a voltage source. A voltage signal induced in a measuring coil (2) is tapped. A coil body (K) carries the excitation coil and the measuring coil. The excitation coil and the measuring coil include a common electrical ground connection. The coil body is designed as a flat hollow cylinder, where the excitation coil and the measuring coil are arranged inside the cylinder in a common plane (E) perpendicular to a cylinder symmetry axis (Z). An independent claim is also included for a method for testing eddy-current with an eddy-current probe.

Description

The The present invention relates to an eddy current probe according to the preamble of claim 1 and to a Wirbelstromprüfverfahren using such an eddy current probe.

Wirbelstromprüfsonden, as will be described below in the context of the invention generally for example for the determination of material properties, such as residual stresses of samples or objects used. In such an exam be through a coil (excitation coil) that has a changing magnetic field generates induced eddy currents in the conductive material to be examined. During the measurement, the eddy current density is then determined by means of the eddy current probe detected by the magnetic field generated by the eddy current in the material, wherein, to measure this magnetic field, a second coil of the eddy current probe, the measuring coil is used. In eddy current testing is exploited in particular that, for example, impurities or damage in an electrically conductive Material has a different electrical conductivity or permeability than the actual one Have material. The measuring signal depends in particular of the three parameters conductivity of the Materials, permeability of material and distance between eddy current probe and material surface. Fields of application of eddy current testing are in particular crack tests or layer thickness measurements.

Surface treatments such as shot blasting, laser blasting or polishing Low ductility components are used in industrial applications Application widely used, z. B. for the treatment of aircraft components. Components that correspond accordingly Surface treated were, can by deliberately introduced near-surface residual stresses on the Components exercised Balancing tensile loads and thus the life of such components significantly extend. The determination or measurement of such near-surface residual stresses is thus important. The measurement happens here above all else with eddy current probes, in particular with the aid of eddy current probes, the have an air core.

For training such eddy current-based measuring systems is the concrete structure the eddy current probe used crucial. Especially at higher Frequencies, this design affects the behavior and properties of the measuring system considerably. In this case, it is particularly critical that the behavior of eddy current probes with air core at high measuring frequencies can be very different, as the behavior at lower frequencies. In particular, parasitic capacitances of the air core eddy current probes significantly influence this the sensor properties, such as sensor sensitivity, that by partial or total lifting of the sensor from the to be measured Object caused uncertainties and the occurring resonance frequencies. In particular, research has shown that the spurious self- and stray capacitance effects an accurate measurement of eddy current induced conductivity changes make it very difficult at frequencies above 25 MHz, in particular since even the smallest, only partially lifting the probe from Object a big one Has influence.

Especially the distributed stray capacitances of Air core eddy current probes are essential for development an eddy-current-based residual stress measurement at frequencies above 25 MHz. The amount of stray capacitance depends heavily from the winding geometry and the presence of any conductive elements or surfaces from.

The The object of the present invention is therefore known eddy current probes in terms of their stray capacitance properties to improve so that in particular accurate measurements in the frequency domain above about 25 MHz are possible.

These The object is achieved by an eddy current probe according to claim 1 and by an eddy current test method, which uses a corresponding probe, solved according to claim 14. advantageous embodiments can be dependent on each claims remove.

following For example, the present invention will first be described in general terms. Close this description several advantageous embodiments with which is described as an eddy current probe according to the invention can be realized. The individual features of the invention the specific embodiments can However, in the context of the invention not only in a combination such they in these embodiments is shown, but also within the scope of the invention be formed or used any other combinations become. In the specific embodiments described below are each the same features or corresponding characteristics denoted by identical reference numerals.

The basic idea of the present invention is to design or electrically contact the excitation coil and the measuring coil of the eddy current probe such that both coils have a common ground or a common ground have seanschluss. This causes the same electrical reference point to be obtained for both coils and to reduce interference (in particular coupling noise between the two coils). In addition, such a design of a common ground connection means that instead of 4 electrical connections for the two coils only a total of 3 electrical connections for these two coils are necessary. Thus, only 3 instead of 4 connection pads are needed.

In a particularly advantageous embodiment variant of this is common ground connection in conjunction with a special coil arrangement realized as follows: The measuring coil and the excitation coil are in a plane (or on a curved surface) as 2 intertwined or nested spirals realized. These two Spirals thus have a common center in which the innermost winding or winding of the spiral of the measuring coil electrically is connected to the innermost turn of the excitation coil. Locally This compound is then the common ground connection or realized the common ground connection of the two coils. The second electrical contact of each of these two coils is then on the outer circumference of the realized respective coil spiral.

In a particularly advantageous embodiment of this spiral arrangement the excitation coil and the measuring coil then takes the height of the individual Windings of these coils towards the center of the spirals (or Place of arrangement of the common mass) to and at the same time decreases in this direction, the width of the individual spiral windings of the two Spools off (under height Here is the extent of the spiral windings perpendicular to the plane or to the area understood, in or on which the two coils are arranged; Width is the extent of the individual spiral windings perpendicular to it or understood in the plane or the surface). This approximately Optimized in the form of a flat cone trained coil design the current distribution (in the two coils or in by the common ground connection resulting coil it comes to a change the current distribution between the turns in the coil center and those at the coil edge) and thus reduces the losses in the coils or the coil, in particular the energy losses due to a uneven power distribution, without this the stray capacitance he increased would. As described, it is particularly advantageous here, both a broadening the coil windings to the outside, and at the same time a reduction in the height of the coil windings Outside to realize. However, it is also possible to only reduce the Height after Outside or only a reduction in the width towards the inside realize.

advantageously, The two nested spirals are designed so that the inner diameter of the spiral windings (distance of the inner Windings from the center) as small as constructively possible, So much smaller than the outer diameter the utmost Coil windings (or the distance of the outermost coil windings for Center). Such small inner diameters also reduce the parasitic capacities in the high frequencies.

In a further advantageous variant, at least 6 turns, prefers significantly more than 6 turns, per coil (measuring coil as Excitation coil, the number of individual turns of these two Coils is particularly in the above-described spiral realization the same): In contrast to the previously accepted assumption do not take the parasitic capacitances with the number of turns in high-frequency applications the coils too. Usually form between the individual turns and between turns and sample capacities, so that the overall capacity increases Winding number also increases. By this special kind of the above Arrangement of the coils (nested spiral arrangement in one Plane or on a surface) or by the nature of the capacitive network consisting of capacitances in parallel and in series, this effect occurs in the present Invention however not so on. The total capacity remains on the contrary from 6 turns almost constant; So the probe can be used in a high frequency Range a significantly higher Winding number have (for example, 20, 50, 100 or more turns). Thereby also results in a higher sensitivity the eddy current probe and a higher Performance of the probe by higher inductance (without increasing the overall stray capacity at high frequencies would).

The three connecting lines necessary for the eddy current probe (two electrical contacts for the two coils on the outer edge of the coil and an electrical contact or common ground in the coil center) be in a particularly advantageous variant perpendicular to the coils or to the plane of the coil assembly or the surface in which the coils are arranged are, led. This has the advantage that these connecting lines the turns The coils do not cross, causing interference, such as noise and capacitive Effects can be avoided. As more closely below described, the connecting lines are advantageously through narrow holes realized in a substrate on which the coils are arranged.

It there are round holes in the substrate, which has a slightly larger diameter have as the connecting lines to the coil. The holes are located exactly over the connection points to the coils and lead the connecting lines vertically away from the coil.

In a further advantageous embodiment, the two coils of the eddy current probe at the outer edge of an annular spacer block be surrounded, over the entire coil geometry a precisely constant adjustable Distance between measuring and Excitation coil and the sample to be measured allows. The block is therefore made of a non-deformable material (for example a metal).

Provided not even surfaces a sample can be measured, the distance block and the carrier substrate (on which the coil windings are arranged) also not flat, but curved (in adaptation to the curved surface of the object to be measured), so that too on such curved sample areas the distance between the individual coil windings and the sample over the entire sensor or coil surface remains constant. The distance block is then to be designed so that the coil distance to the object to be measured is constant everywhere.

The inventive eddy current probe is, as from the specific embodiments yet becomes clear, designed as an eddy current probe with air core. In a In another advantageous variant, the space, which of the coils, the spacer block, the other inner surfaces of the probe and to be measured Sample is carried out as a vacuum area. This is done by means of an opening in the probe wall (for example, in the substrate on which the coils are arranged and in the underlying wall areas) after Put the sensor on the sample a vacuum in this interior generated. Such a vacuum on the one hand has the advantage that so that the Sensor adheres to the sample without further attachment and secondly that a vacuum is the parasitic capacities the coil further reduced and the set at very high frequencies thus further improved.

It demonstrate:

1 A first embodiment of an eddy current probe according to the invention in cross section,

2 a plan view of the coil windings of the eddy current probe 1 .

3 the interior of an eddy current probe according to a second embodiment of the invention,

4 an inventive eddy current probe in the form of a third embodiment,

5 the current distribution in the first turn in the probe coils of the embodiment according to 1 .

6 the total capacity as a function of the inner diameter w _{i of} the eddy current probe according to 1 and

7 the total capacity as a function of the number of coil turns in Embodiment 1.

1 shows a first inventive eddy current probe in cross section through the axis of symmetry Z. This eddy current probe has an eddy current body (supporting bobbin K), which in the present case, a cover element (box 8th ), a distance block connected to it 9 , one inside the through the spacer block 9 and the lid member 8th trained, one-sided open hollow body arranged substrate 6 as well as between this substrate 6 and the inner wall of the lid member 8th arranged connecting element 7 between substrate 6 and cover element 8th having. The cover element 8th as well as the distance block 9 together form a one-sided open, flat hollow cylinder whose one cover surface (lying in the figure below) is open and the other cover surface (lying in the figure above) through the base of the box 8th or the cover element 8th is closed. The circular base of the box 8th thus forms the upper end of the shown, one-sided open hollow cylinder, whereas the other wall sections of the box 8th and the spacer block disposed adjacent thereto 9 form the side walls of the half-open hollow cylinder. The height of the hollow cylinder (in the direction of the cylinder axis of symmetry Z) here is approximately the hollow cylinder diameter (expansion of the hollow cylinder perpendicular to the cylinder axis of symmetry Z). The carrying bobbin K is thus (as well as the entire eddy current probe) rotationally symmetrical about the symmetry axis Z formed.

In the hollow cylinder 8th . 9 trained interior I is on the inside of the box 8th a flat circular connecting element 7 symmetrical about the axis Z adjacent to the base of the box 8th arranged. This has a smaller diameter than the inner wall of the other wall sections of the box 8th on and carries on its inside the box 8th opposite side and also in the interior I of the hollow cylinder a Sub stratschicht 6 which is also formed in the form of a flat, circular disc and arranged symmetrically about the axis Z. This substrate 6 is as a carrier of the excitation coil 1 and the measuring coil 2 (see the following paragraphs) formed and also has a smaller diameter than the inner wall of the other wall sections of the box 8th on.

On the connecting element 7 opposite, shown in the figure below and formed as a flat surface surface of the substrate 6 are in a common plane E parallel to this surface of the substrate 6 both the excitation coil 1 as well as the measuring coil 2 arranged as described below.

2 shows a plan view of the arrangement plane E of the excitation coil 1 and the measuring coil 2 , As 2 shows, these two coils are in the form of two nested spirals 1a . 2a arranged in the plane E: the excitation coil 1 is as a first level spiral 1a trained, the measuring coil 2 as a second plane spiral, the two spiral planes being identical. The turns of the first spiral 1a and the turns of the second spiral 2a are each offset from each other and arranged at a constant distance from each other nested, so that two nested, concentric spirals run into each other: following the turns of the spiral 1a the excitation coil 1 from outside to inside (ie towards the central axis Z or to the common center Z of the two spirals), so you can the excitation coil 1 as an inwardly running or incoming first spiral, whose inner end in the region of the center Z is an electrical connection to the inner end of the second spiral 2a the measuring coil 2 having. From this inner connection in the center Z then run the turns of the spiral 2a (outgoing spiral) of the measuring coil 2 at ever greater distances from the center Z outwards to the outer circumference of the two spirals out between the individual turns of the incoming spiral 1a ,

Two adjacent turns of the expiring spiral 2a (This also applies to the incoming spiral 1a ) have a distance of d from each other. Due to a symmetrical offset of the windings of the first spiral 1a and the second spiral 2a is the distance of a turn of the first spiral 1a to the adjacent turn of the second spiral 2a thus d / 2.

In the center Z of the two spirals is now the electrical contacting of the inner winding of the first spiral 1a and the inner turn of the second spiral 2a in the form of the common ground connection 3 the two coils 1 and 2 educated. Overall, only three electrical contacts are thus required: The common ground connection 3 in the center Z and in each case one with respect to the center Z seen external electrical contacting of each of the two coils 1 . 2 in the form of a contact pad 4 is formed (the electrical contact pad 4-2 contacts the outermost coil turn of the second coil 2a , the electrical contact pad 4-1 contacts the outermost turn of the first coil 1a ).

The electrical contacting of the two contact pads 4-1 and 4-2 as well as the common mass 3 are now realized as follows: At the location of these three electrical contacts in each case in the direction of the cylinder axis Z, that is perpendicular to the spiral plane E, a bore in the substrate 6 , the connecting element adjacent thereto 7 and the adjoining lid area of the box 8th brought in. In these round holes with the smallest possible diameter are connecting cable 5 introduced (there are thus a total of three connecting cables 5 necessary). The operation of the eddy current probe is then as follows: Between the connecting line 5a that the outer contact pad 4-1 the excitation coil 1 contacted and the central connection line 5a that the common ground connection 3 contacted the two coils, with the aid of a voltage generator, for example, a sinusoidal voltage U _E applied (operation of the excitation coil). The eddy current field modified by the object O to be measured (symbolized here merely by arrows) is then detected by the fact that between the outer contact wheel 4-2 the measuring coil contacting connecting line 5b and the connection line to the ground terminal in the measuring coil 2 induced voltage U _A is tapped (the central connecting line and the central ground terminal because he or she thus both the operation of the excitation coil 1 as well as the voltage tap with the help of the measuring coil 2 is used, here with two reference numerals 5a . 5b Mistake).

As 1 indicated by the arrows, the eddy current probe according to the invention is placed with its underside on the arranged in the outer space A, to be measured object O. The extent of the distance block 9 in the symmetry axis direction Z is chosen so that by the spacer block 9 formed lower edge of the eddy current probe has a distance D from the spiral plane E. The distance block 9 is designed here as a symmetrical circular ring, so that due to the arrangement of the coils 1 . 2 have in the plane E all coil turns of the two coils when placing the eddy current probe on a flat surface of an object O the same distance to this surface of the object O have. This provides optimal detection of the we modified by the object O. current field through the measuring coil 2 for sure.

As 2 shows, the inner turns of the coils extend 1 . 2 also so far inward towards the center Z, that the innermost turn of the coils 1 . 2 have the smallest possible distance to the center Z. The ratio of the distance of each outermost turn of the two coils 1 . 2 from the center (distance w _a ) and the distance of the innermost turn of the two coils 1 . 2 from the center Z (distance w _i ), ie the ratio V = w _a / w _i here is about 5. The choice of the smallest possible inner distance w _i or the largest possible ratio V reduces the parasitic capacitances in the high frequencies achieved by the above-described geometry, continue.

In the present example, the following materials were used for each device: copper for the excitation coil 1 , the measuring coil 2 , the earth connection 3 , the two connections to the outer coil turns 4-1 and 4-2 as well as the connection cables 5 , The substrate 6 is made of plastic or other non-metallic material. It is important here to have the lowest possible relative permittivity ∈ _r (therefore, for example, glass or FR ₄ can be used).

FR4 (Flame Retardant 4) is a circuit board material that is widely used is. It consists of glass fiber mats soaked in epoxy resin. It is fireproof, a very good insulator with very low permittivity, low loss in high frequencies and has high strength and rigidity. FR4 is mainly used because of its low permittivity.

The connection 7 between substrate 6 and lid section of the box 8th is also made of plastic or other non-metallic material. The box 8th itself as well as the distance block 9 are made of brass (but other metals can be used).

3 shows a second embodiment of an eddy current probe according to the invention. This is basically like the one in the 1 and 2 constructed eddy current probe, so that only the differences will be described below. For the sake of clarity, moreover, only the substrate is here 6 as well as the coils 1 . 2 along with their electrical connections (pads 4 as well as ground connection 3 ). As in the example of 1 and 2 the two coils are arranged here in one and the same plane E. From the outermost coil windings of the coils 1 . 2 However, as seen from the center Z of the coils, the height of the individual coil turns (extension of the turns in the direction of the Z axis) increases with both coils 1 . 2 to. Likewise, the extent of the individual coil turns perpendicular to the axis Z or seen in the spiral plane E (width of the turns) from outside to inside towards the center from. The decrease in the width and the increase in the height inwards are designed in the present case such that the cross-sectional area of the individual coils (winding cross-sectional area) remains constant. This broadening of the turns while reducing the winding height reduces the otherwise resulting energy loss due to a non-uniform current distribution in the individual windings without increasing the stray capacitance.

4 shows a further embodiment of an eddy current probe according to the invention in an analogous cross-section, as shown in the 1 and 3 is shown. Also, this eddy current probe is constructed, except for the differences described below, as well as the 1 and 2 described eddy current probe.

The surface of the substrate facing the object O (not shown) 6 Here, a slight (seen in the figure below the probe object O from convex and from the lid surface of the box 8th seen from concave) curvature up. The spools 1 . 2 are thus not arranged in a plane E, but on a slightly curved surface of the substrate 6 , At a distance D from this surface of the substrate 6 is now that area of the spacer block 9 , which serves to place the probe on the object O, also provided with a corresponding curvature. This surface of the spacer block 9 and the lower surface of the substrate 6 are in terms of their curvature designed so that they are the surface of the object to be measured O aligned. As a result, it is ensured even with non-planar scanned surfaces of objects O that all coil turns 1a and 2a have the same distance to the object surface.

Another aspect realized in this embodiment is denoted by the reference numerals 10 and 11 Designated: By a in the cover surface of the box 8th introduced bore B is a suction opening 10 formed, which with a vacuum pump 11 is in communication. If the probe is using the spacer block 9 sealingly placed on the surface to be measured of the object o, so the interior of the hollow cylinder (interior I) by means of the vacuum pump 11 be evacuated. On the one hand, this causes a further reduction of the disturbing stray capacitances of the arrangement and, on the other hand, also a secure holding of the object O on the probe.

5 illustrates the current distribution in a coil winding at different measurement frequencies. For six frequencies, the current density in each case is shown side by side in the same rectangular winding cross-section. The measurement frequency increases from the leftmost rectangular cross section (1 MHz) to the rightmost rectangular cross section (100 MHz). The dark areas symbolize the highest current density, the lighter areas symbolize lower current densities. At a low measurement frequency of 1 MHz in the leftmost rectangle, the current density across the entire cross section is consistently high. As the measuring frequency increases, a high current density is increasingly found only at the outer edge of the winding cross-section. This current flow, which is pushed to the edge of the conductor, is caused by the skin effect. This figure illustrates the very large influence of coil geometry in high-frequency eddy current measurement. Using a simulation program developed for this situation, optimal geometric parameters for high-frequency eddy current coils could be developed.

6 shows in a diagram the total capacity of an eddy current coil, plotted against the inner diameter. It can be seen that as the inner diameter increases, the overall capacity also increases linearly. Based on this statement, the one claim that requires the smallest possible inner diameter justified, whereby the parasitic total capacity is very low and thus the coil is better suited for high measurement frequencies.

7 shows in a diagram the total capacity of an eddy current coil plotted against the number of coil turns. The highest value reaches the parasitic capacitance with a number of turns of 2 and then decreases exponentially up to a number of turns of 6. After this optimally low capacitance value with 6 turns, the capacity increases only slightly with increasing number of turns linearly. This context illustrates the set forth in a claim advantageous variant of the invention that the eddy current coil should have the highest possible number of turns. Although the parasitic capacitance increases slightly from a number of turns of 6, its inductance increases considerably more, which considerably improves the sensitivity of the coil.

Claims (16)

Eddy current probe comprising an excitation coil connectable to a voltage source ( 1 ) for generating a magnetic field at the location of an object to be measured (O), a measuring coil ( 2 ), from which a voltage signal induced in it can be tapped off and an excitation coil ( 1 ) and the measuring coil ( 2 ) carrying bobbin (K) characterized in that the excitation coil ( 1 ) and the measuring coil ( 2 ) a common electrical ground connection ( 3 ) exhibit. Eddy current probe according to the preceding claim, characterized in that the excitation coil ( 1 ) at least in sections as a substantially planar first spiral ( 1a ) and the measuring coil ( 2 ) at least in sections as a substantially planar second spiral ( 2a ), wherein the turns of the first spiral and those of the second spiral offset from each other and from a common spiral center outwardly, each alternately so that the two spirals ( 1a . 2a ) form two concentric spirals (incoming and outgoing spirals), which are nested one inside the other and spiral in one plane (E). Eddy current probe according to the preceding claim thereby marked that the common ground connection in the center (Z) of the two spirals is formed and or that both spirals in the form of two archimedean one another Spirals (same distance from winding to winding) formed are. Eddy current probe according to one of the two preceding claims, characterized in that the number of turns of the first spiral ( 1a ) and / or the second spiral ( 2a ) is at least 5, preferably at least 10, preferably at least 20, preferably at least 50. Eddy current probe according to one of the previous three claims thereby marked that the width of the individual spiral windings in the spiral plane from the outside decreases towards the spiral center and or that the height of individual spiral windings perpendicular to the spiral plane from the outside to Spiral center increases, being particularly preferred both aforementioned features are realized simultaneously. Eddy current probe according to one of the four preceding claims, characterized in that the ratio V = w _a / w _{i of} the distances of the outermost turn (w _a ) and the innermost turn (w _i ) from the spiral center (Z) in the first spiral ( 1a ) and / or at the second spiral ( 2a ) is greater than 2, in particular greater than 3, in particular greater than 5, in particular greater than 10. Eddy current probe according to one of the preceding claims, characterized in that the bobbin (K) as one side with a cover element (box 8th ) closed and on the opposite side (bottom) open, flat hollow cylinder ( 8th . 9 ), wherein the excitation coil ( 1 ) and the measuring coil ( 2 ) in the interior of the hollow cylinder and spaced from the bottom and connected to the lid member ( 6 . 7 ) are. Eddy current probe according to the preceding claim, characterized in that the excitation coil ( 1 ) and the measuring coil ( 2 ) are arranged in the interior of the hollow cylinder substantially in a plane (E) perpendicular to the cylinder axis (Z). Eddy current probe according to the preceding claim, characterized in that the excitation coil ( 1 ) and the measuring coil ( 2 ) are arranged in the interior of the hollow cylinder on a in the region of the cylinder axis (Z) on this axis substantially perpendicular and radially outward, in the region remote from the cylinder axis at least in sections, seen from the cover element from a concave curvature having surface. Eddy current probe according to one of the preceding claims characterized by an arrangement of the excitation coil ( 1 ) and the measuring coil ( 2 ) substantially in a plane (E), wherein with the excitation coil ( 1 ) connected lines ( 5a ) for connecting the excitation coil ( 1 ) with a voltage source and / or with the measuring coil ( 2 ) connected signal lines ( 5b ) for tapping a voltage signal from the measuring coil ( 2 ) extend substantially perpendicularly away from this plane (E). Eddy current probe according to one of the preceding claims, characterized by a spacer block ( 9 ), the excitation coil ( 1 ) and the measuring coil ( 2 ) substantially annularly surrounds and is shaped so that with its help when placing the eddy current probe on a surface of the object to be measured, a substantially constant distance between this surface and the coil turns of the excitation coil ( 1 ) and the measuring coil ( 2 ) can be produced. Eddy current probe according to the preceding claim, characterized in that the spacer block ( 9 ) is a non-deformable solid and / or consists of or comprises a metal. Eddy current probe according to one of the preceding claims, characterized in that the bobbin (K) is shaped in this way and a suction opening (B) leading from the body interior (I) to the outside (A) of the body ( 10 ) which is formed so that by means of a to the suction opening ( 10 ) connectable and / or connected vacuum generator, in particular a vacuum pump ( 11 ), after placing the eddy current probe on the object to be measured in the bobbin interior a vacuum can be generated. Eddy current test method in which an eddy current probe comprising an excitation coil connected to a voltage source (US Pat. 1 ) for generating a magnetic field at the location of an object to be measured (O), a measuring coil ( 2 ), from which a voltage signal induced in it can be tapped off, and an excitation coil ( 1 ) and the measuring coil ( 2 ) carrying bobbin (K), wherein the excitation coil ( 1 ) and the measuring coil ( 2 ) a common electrical ground connection ( 3 ), is placed on the object to be measured (O), wherein by means of the voltage source, an AC voltage is applied to the excitation coil and in which the voltage induced in the measuring coil voltage signal is tapped and evaluated. Eddy current test methods according to the preceding, characterized in that an eddy current probe according to one of the preceding eddy current probe claims the object to be measured (O) is put on. Use of an eddy current probe or an eddy current test method according to one of the preceding claims for testing the material properties an object to be measured, in particular for crack detection or Layer thickness measurement on the object.