DD257371A3 - Eddy Current Tester - Google Patents

Abstract

The invention relates to the non-destructive Werkstoffpruefung electrically leitfaehiger materials z. B. of paints u. ae. are covered, whereby a veraenderlicher distance can occur to Werkstueckoberflaeche. The aim is to improve the reliability of the test results. The object is to eliminate the interference effect of the distance fluctuations while simultaneously determining their permissible values. According to the invention, this object is achieved by the fact that the eddy current testing device, which has a high-frequency generator, two eddy current probes as constituents of two resonant circuits, two amplitude detectors, a tuning unit for the high-frequency generator and a signaling unit, wherein the second eddy current probe is movable in the direction perpendicular to the workpiece surface to be tested, characterized in that the Wirbelstrom-Pruefgeraet a Differenzverstaerker whose inputs are connected to the outputs of the amplitude detectors, and a subsequent comparator whose output is via a Verzoegerungsleitung at the return input of the tuning unit for the high frequency generator, via a loadable by the comparator controlled tuning buffer whose content can be returned to the tuning unit via a second, externally controllable gate, a displacement measuring unit with associated displacement transducer, a second, from the comparator steu having gate and a buffered display, wherein the second eddy current probe is switched on via a third gate.

Description

Field of application of the invention

The invention relates to an eddy current testing device for nondestructive testing of electrically conductive materials. It is particularly suitable for testing materials that are resistant to dielectric layers, eg. As paints o. A., Are covered, wherein a variable distance between eddy current probe and material surface may occur.

Characteristic of the known state of the art

Eddy current defectoscopes are known which have a high-frequency generator with an eddy current probe in the resonant circuit (Technicskie characteristic! Sovetskogo pribora PPD in: Probory nerazrusajuscego kontrolja, vol. 2 under the editorship of V. V. Kljuev, 1976). They allow a crack test on the surface of electrically conductive materials, but only at a constant distance of the eddy current probe surface to be tested.

Modern eddy current defectoscopes, eg. As the device WD-801, are equipped with electrical circuits to reduce the interference caused by variable probe spacing, but have a significant reduction in the sensitivity to.

The invention comes closest to a device (Technical Information of the Fa. Förster to device: "Defectometer H 2.835") / which has a high-frequency generator, an eddy current probe as part of a resonant circuit, an amplitude detector, a tuning unit for the generator and a signaling unit.

The main disadvantage of this device, since the Abhebeeffekt can be effective as a disturbance, in insufficient accuracy. Its influence is merely suppressed by the signal being corrected in the processing unit when the probe is removed from the test object.

Other known arrangements, such as e.g. proposed in SU-US 993111, use more extensive configurations with periodically tuned oscillators and perform the material testing pointwise during the vertical movement of the probe, so that virtually the Abhebeeffekt is also considered for the measurement. However, this solution is because of the point-wise approach of low utility value.

In EP-ES 42881, the compensation of the lift-off effect is proposed by a favorable operating point determined from two distance values of the probe. Nutzwertmindemd acts here that the influence of Abhebeeffektes only with respect to an operating point, and this would be eliminated only with considerable effort.

Also equipped with two probes device, wiez. As shown in DE-OS 3130 685, is so far only able to suppress the Abhebeeffekt within a small range. The reliability of the test results is therefore limited and thus limits the utility of the known solutions.

Object of the invention

The object of the invention is to improve the reliability of the test results and thus in an increased utility value of the eddy current testing device.

Explanation of the essence of the invention

The object is to eliminate the disturbing influence of the distance fluctuations while simultaneously determining their maximum permissible values.

According to the invention the object is achieved in that the eddy current testing device, which has a high frequency generator, two eddy current probes as components of two resonant circuits, two amplitude detectors, a tuning unit for the high frequency generator and a signaling unit, wherein the second eddy current probe is movable in the direction perpendicular to the workpiece surface being tested, characterized in that the eddy current testing device a

Differential amplifier whose inputs are connected to the outputs of the amplitude detectors and a subsequent comparator whose output is connected via a delay line at the reset input of the tuning unit for the high-frequency generator, via a controlled by the comparator gate tuning buffer whose content via a second externally controllable gate again the tuning unit can be supplied, a Wegmeßeinheit with associated transducer, a second controllable by the comparator gate and a buffered display, wherein the second eddy current probe is switched on via a third gate.

embodiment

The eddy current testing device according to the invention will be explained in more detail using an exemplary embodiment. The accompanying drawings show in FIG

Fig. 1: the block diagram of the eddy current testing device according to the invention and

Fig. 2: a possible mechanical construction of the eddy current probe in conjunction with the transducer of Wegmeßeinheit.

According to FIG. 1, the eddy current testing device has the following structure: An eddy current probe 2 and a port 3 are connected to the output of a high-frequency generator 1, which is followed by a second eddy current probe 4 with identical electrical properties to the probe 2. The outputs of the eddy current probes 2 and 4 are applied to the inputs of two amplitude detectors 5 and 6. The outputs of these amplitude detectors 5 and 6 are connected to the inputs of a differential amplifier 7 whose output is connected via a comparator 8 and a delay line 9 to the reset input of a tuning unit 10 for the high-frequency generator 1. The data output of the tuning unit 10 is furthermore coupled to the input of a tuning buffer 12 via a gate 11 that can be controlled by the comparator 8. This tuning buffer 12 in turn is followed by an externally controllable gate 13 and the data input of the tuning unit 10. With the eddy current probe 4, a displacement transducer 14 is mechanically connected. The electrical output of this transducer 14 is located at the entrance of a Wegmeßeinheit 15 whose output is connected via a controllable by the comparator 8 Tor 16 with a buffered display 17. The control input of the gate 13 is also coupled to the control input of the gate 3. In addition, there is a signaling unit 18 at the output of the amplitude detector 5.

The possible mechanical probe construction with the eddy current probes 2 and 4 shown in FIG. 2 consists of two identical ferromagnetic coil cores 19 and 20, on which two identical windings 21 and 22 are applied. The eddy current probe 4 is movably mounted. With the aid of a plunger 23 which is fixedly connected to the core 20, this probe 4 can be lowered against the force of a spring 24 on the workpiece surface 26. Mechanically fixed to the plunger 23 of the transducer 14 is coupled

 A housing 25 receives the probe construction

 The device works in the following way:

After placing the probe unit with the eddy current probes 2 and 4 on the workpiece surface to be tested 26, the plunger 23 of the eddy current probe 4 is depressed and thus placed the eddy current probe 4. Now the tuning unit 10 begins to reduce the frequency of the high-frequency generator 1. Its output voltage passes directly to the eddy current probe 2 and via the gate 3 to the eddy current probe 4. The output signals of both eddy current probes 2 and 4 are converted in the amplitude detectors 5 and 6 into corresponding DC voltages before they reach the inputs of the differential amplifier 7. The comparator 8, at whose input the output voltage of the differential amplifier 7 is located, supplies at its output as long as no voltage as the difference of the output voltages of the amplitude detectors 5 and 6 exceeds a value to be determined beforehand. If the differential voltage at the output of the differential amplifier 7 is small enough, d. H. If both eddy current probes 2 and 4 supply the same output voltage, the comparator 8 responds. At this moment, the set test frequency ensures the detachment-insensitive test in a distance range corresponding to the current distance difference of the two eddy current probes 2 and 4 from the workpiece surface 26 to be inspected. ,

The L / H edge at the output of the comparator 8 briefly opens the gates 11 and 16. Thus, on the one hand, the signal of the transducer 14, in conjunction with the Wegmeßeinheit 15, the instantaneous removal of the eddy current probe 4 from the workpiece surface to be tested 26 as an electrical signal holds over the gate 16 in the buffered display 17 and can be read there. On the other hand passes through the open gate 11 at the same time the tuning of the tuning unit 10 in the tuning buffer 12, where it is ready for eventual later use. Finally, the L / H edge of the comparator 8 passes via a delay line 9 to the reset input of the tuning unit 10, which again adjusts the maximum possible frequency value in the high-frequency generator 1 and gradually lowers it. This completes the first tuning cycle and begins the next one.

Now, if the plunger 23 of the probe is lifted, the eddy current probe 4 moves away from the surface to be tested 26. The Abstimmzyklüs described repeats itself automatically until for the current distance eddy current probe 4 to workpiece surface 26 no equality of the output voltages of the amplitude detectors 5 and 6 can be reached. However, even in the buffered display 17, the last distance value is still available for a successful adjustment and thus indicates that maximum distance of the eddy current probe 4 from the workpiece surface to be tested, from which it is still possible to test it against detachment. This display content also persists during the subsequent test procedure. This test procedure is initiated with an external pulse on the gates 13 and 3. The short-opening gate 3 conveys the contents of the tuning buffer 12, which contains the last successful voting value, in the tuning unit 10, which thus sets the test frequency in the high frequency generator 1, which ensures a distance insensitive test from maximum distance. The external pulse also leads to the permanent closing of the gate 3, so that the differential amplifier 7 is inoperative. The signals of the amplitude detector 5 reach the signaling unit 18 and correspond to discovered material defects.

From the functional description of the proposed eddy current tester it is apparent that it has significant advantages over known devices, in particular with respect to the test accuracy. This is achieved by suppressing the main disturbance-the Abhebeeffektes. It is automatically always that frequency at the high-frequency generator 1 is set, which corresponds to the maximum possible distance between Wirbeistromsonde and workpiece surface, which is additionally displayed.

Particularly advantageous, the device can be used when painted or coated with other non-conductive materials surfaces are tested. Such testing tasks are very often encountered in mechanical and plant engineering as well as in transport.

Claims (2)

Eddy current testing device having a high frequency generator, two eddy current probes as components of two resonant circuits, two amplitude detectors, a tuning unit for the high frequency generator and a signaling unit, wherein the second eddy current probe is movable in the direction perpendicular to the workpiece surface under test, characterized in that the eddy current testing device Differential amplifier (7) whose inputs are connected to the outputs of the amplitude detectors (5; 6) and a subsequent comparator (8) whose output via a delay line (9) at the reset input of the tuning unit (10) for the high-frequency generator (1), a tuning buffer (12) loadable via a gate (11) controlled by the comparator (8), the contents of which can be returned to the tuning unit (10) via a second, externally controllable gate (16), a position measuring unit (15) with associated displacement sensor (11). 14), a second, from the comparator (8) steu having gate (16) and a buffered display, wherein the second eddy current probe (14) via a gate (3) is switched on. For this 2 pages drawings