WO2021140121A1

WO2021140121A1 - Non-destructive materials testing

Info

Publication number: WO2021140121A1
Application number: PCT/EP2021/050131
Authority: WO
Inventors: Stephan Falter
Original assignee: Rosen Swiss Ag
Priority date: 2020-01-06
Filing date: 2021-01-06
Publication date: 2021-07-15
Also published as: BE1027960B1; EP4088109A1; KR20220120672A; CN115066607A; BE1027960A1

Abstract

The invention relates to a transceiver probe system device for a device for materials testing, having a transmitter element with an ultrasound exit face, designed to emit ultrasound to a metal sheet, and a receiver element with an ultrasound entry face, designed to receive ultrasound which is reflected by the metal sheet, and wherein the transmitter element and the receiver element are each divided into multiple sub-elements. The present invention also relates to a device comprising the system. The invention further relates to a method for testing metal sheets, having the following method steps: emitting ultrasound (100) via multiple sub-element ultrasound exit faces of a transmitter element to a metal sheet; and receiving ultrasound (200) reflected by the metal sheet via multiple sub-element ultrasound entry faces of a receiver element. The invention furthermore relates to a computer program, a computer-readable medium and to a data signal.

Description

nondestructive material test

Technical area

The invention relates to a transmitter-receiver test head system (SE test head system) for a device for non-destructive testing of materials.

The present invention also relates to a device for non-destructive testing of materials.

The present invention also relates to a method for non-destructive testing of materials.

The present invention also relates to a computer program in accordance with the aforementioned method, a data carrier signal for transmitting the aforementioned computer program and a computer-readable medium which causes a computer to carry out the aforementioned method.

Background of the invention

So far, SE probes for sheet metal testing are known. A sheet metal test is carried out using ultrasound. Testing using ultrasound is an acoustic method for finding material defects using ultrasound and is one of the non-destructive testing methods.

Description of the invention

Based on this situation, it is an object of the present invention to provide an improved solution for non-destructive testing of materials. In particular, a higher test sensitivity is to be achieved, while at the same time a very good test area in the depth direction is to be achieved.

The object of the invention is achieved by the features of the independent main claims. Advantageous refinements are given in the subclaims. If technically possible, the teachings of the subclaims can be combined as desired with the teachings of the main and subclaims.

Accordingly, the problem is solved by a transmitter-receiver test head system (SE test head system). The system is intended for a device for non-destructive testing of materials, in particular for testing sheet metal. The system has: a transmitter body with an ultrasound exit surface, configured to emit ultrasound onto a sheet metal, and a receiver body with an ultrasound entry surface, configured to receive ultrasound that is reflected on the sheet metal, and the transmitter body and the receiver body each in several Partial bodies are divided.

The system can comprise several test heads or be formed in one piece from one test head. For example, in the case of several test heads, two angle test heads can be used, which together form the transmitter-receiver test head system.

The sub-bodies of the transmitter body each emit ultrasound. The partial bodies of the receiver body each receive ultrasound. The sub-bodies are accordingly functionally independent units of the transmitter body / receiver body that they jointly form.

The invention also relates to a device for non-destructive testing of materials, in particular for testing metal sheets, which has at least one SE test head system. The device can be adapted to the workpiece to be tested. For example, clamping devices for clamping the workpiece are conceivable. A storage system or a transport system for the workpiece to be tested can also be part of the device. The invention also relates to a method for non-destructive testing of materials, in particular for testing metal sheets. The method is carried out in particular with an SE probe system. The method has the following method steps: Radiation of ultrasound, via several partial-body ultrasound exit surfaces of a transmitter body, onto a sheet metal; Receipt of ultrasound reflected on the sheet metal via several partial-body ultrasound entry surfaces of a receiver body.

The method preferably has method steps corresponding to features of an SE test head according to at least one of the modified embodiments described below.

It is preferred that the sequence of process steps can be varied, unless technically required in an explicit sequence. However, the aforementioned sequence of process steps is particularly preferred.

According to the invention, a computer program for carrying out the method according to the invention or one of the advantageous refinements of the method is also specified.

According to the invention, a computer-readable storage medium for carrying out the method according to the invention or one of the advantageous refinements of the method is also specified.

According to the invention, a signal generated by steps of the method according to the invention or one of the advantageous refinements of the method is also specified.

The basic idea of the invention and individual aspects of the claimed subject matter of the invention are explained below and preferred modified embodiments of the invention are described further below. Explanations, in particular regarding advantages and definitions of features, are basically descriptive and preferred, but not limiting, examples. If an explanation is limiting, this is expressly mentioned. The basic idea of the present invention is to form both the transmitter body and the receiver body in several sub-bodies. It has surprisingly been found here that a test sensitivity can be increased considerably as a result. The transmitter body and the receiver body are each referred to as an oscillator, in which case the individual sub-bodies are each sub-oscillator.

The sub-body division and thus the provision of a large number of active elements both on the transmitter and on the receiver side has the advantage that even smaller imperfections in materials can be detected and localized than before. In addition, the measurement results are more reproducible than with previously known methods.

The SE probe system enables sheet metal as part of workpieces and components to be tested non-destructively. For example, the components can be pipes or fuselage parts of aircraft. For example, the SE probe system enables sheet metal to be tested with a close-up resolution in a range from 0.9 mm to 15 mm. A higher test sensitivity corresponding to a circular disc reflector with a diameter of 1 mm to 2 mm is also achieved.

The invention is particularly suitable for the use of phased radiation technology. In phased array technology, the respective partial bodies are excited individually as elements of the transmitter body, e.g. B. to generate each beam. The partial bodies can be excited differently, in particular excited in such a way that generated beam bundles are pivoted or focused.

The invention is suitable for testing corrosion in tank bottoms and pipes.

Workpieces / sheets can be checked for inclusions. Additions change absorption, transmission, reflection or other physical properties on the workpiece to be tested. You can add z. B. Material is missing such as cracks, inclusions, pores, cavities, doublings or other discontinuities in the structure. It can also be z. B. be a duplication error in depth.

The sub-bodies of the transmitter body / the receiver body can each have the same size ultrasound exit / entry area or with different sizes Ultrasound exit / entry surface be designed. Mixed solutions are also conceivable in which some of the sub-bodies are configured with ultrasound exit / entry surfaces of the same size and some of the sub-bodies are configured with different-size ultrasound exit / entry areas per transmitter body / receiver body. It is particularly preferred that the ultrasound exit / entry surfaces of all partial bodies are designed to be the same size, which advantageously simplifies control and evaluation. Depending on the desired resolution, differently sized ultrasonic exit / entry areas can be advantageous.

The test head system can also have a plurality of partial bodies arranged at a distance from one another on its transmitter body / receiver body. The transmitter body / receiver body can also be designed to be of different sizes.

According to a modified embodiment of the invention, the SE test head system has a different number of transmitter bodies and receiver bodies. The number of receiver bodies is particularly preferably greater than the number of transmitter bodies. This advantageously allows an area to be enlarged within which the system detects defects in the workpiece to be tested.

An SE probe system is such a system consisting of a transmitter body and a receiver body separate from it, which are arranged at an angle to one another. The angle is used to ensure that the transmit and receive beams form an overlapping area. The ultrasound 1 exit surface of the transmitter body is accordingly not in a common plane as the ultrasound entry surface of the receiver body.

In particular, the transmitter body and the receiver body are arranged in such a way that they enclose an obtuse angle. In particular, the ultrasound exit surface of the transmitter body and the ultrasound entry surface of the receiver body are arranged in such a way that they enclose an obtuse angle. This obtuse angle is also known as the roof angle. In other words, the two transmitter / receiver bodies designed as oscillators are inclined by the obtuse angle (roof angle) with respect to the normal or parting plane. Depending on the implemented roof angle inclined leading sections of the length are glued under the transducer, which results in the maximum sensitivity in a given depth range.

In addition to the transducers, an SE probe system includes wedges on which the transducers are attached. The wedges are lead lines that z. B. made of sound-conducting plastics such as polymethyl methacrylate (abbreviated: PMMA) or polystyrene (abbreviated: PS). There can be an acoustic adaptation layer between the transducer and the wedge. The thickness of the matching layer can correspond to a quarter wavelength of the probe system. It is used in particular to adapt an impedance and optimal sound transmission between the transducer and the flow on the transmitter and receiver side. With an SE probe system, the near-field resolution can be varied over a wide range by choosing the roof angle, the distance between the transmitter and the receiver and the length of the leading wedge. This creates a dead zone of the probe system, i. H. undetectable zone in the workpiece. In the case of large roof angles, the ultrasound is sounded into the workpiece to be tested at an angle and not perpendicular to the surface. With an increase in the roof angle, a so-called “detour error” occurs, which results in an increase in the running time and thus e.g. B. is reflected in an error in the wall thickness measurement. This error can be compensated for by adjusting the ultrasound system or mathematically with digital devices.

In the case of the SE probe system according to the invention, it is primarily made possible that a dead zone is considerably reduced. A compromise solution when choosing a roof angle is therefore less important.

According to a modified embodiment of the invention, the receiver body and / or the transmitter body are cuboid. It is particularly preferred that the transmitter and / or receiver body form a cuboid which has three pairs on surfaces of the same size. In the case of a rectangular configuration of the ultrasound exit surface of the transmitter body and the ultrasound entry surface of the receiver body, an axis is defined as the longitudinal axis that lies in the plane of the ultrasound entry or exit surface and is parallel to the longer sides of the rectangular ultrasonic entrance or exit surface extends. In other words, the SE probe system is designed as a broad beam probe.

The transverse direction corresponds to a direction which, starting from the transmitter body, points to the receiver body or, conversely, points from the receiver body to the transmitter body. The longitudinal direction corresponds to a direction that is transverse to the transverse direction. The longitudinal direction can correspond to a direction of the greatest extent of the ultrasound entry surface of the receiver body or the exit surface of the transmitter body, d. H. in the direction of the longitudinal axis, d. H. point parallel to the longitudinal axis, the transmitter body or the receiver body. The transverse direction can correspond to a direction perpendicular to the greatest extent of the ultrasound entry or exit surface and, in particular, point orthogonally to the direction of the longitudinal axis of the transmitter body or the receiver body.

According to a modified embodiment of the invention it is provided that the receiver body is divided into several sub-bodies in the transverse direction, in particular transversely to its longitudinal axis, and / or the transmitter body is divided into several sub-bodies in the transverse direction, in particular transversely to its longitudinal axis. Particularly preferably, the receiver body is divided into a plurality of sub-bodies transversely to its longitudinal axis. A division in the transverse direction improves the resolution of the probe system. In particular, a division of the receiver body favors an improved lateral test resolution, in particular in the transverse direction. A design of the receiver body in the transverse direction with several sub-bodies increases the resolution in the transverse direction by considering groups of sub-elements which can also overlap. Data from such receiver bodies, also known as virtual receiver bodies, can be evaluated in parallel and therefore quickly. In the case of a division in the longitudinal direction, in particular in the case of the receiver body, it has surprisingly been found that a testable depth range in the sheet metal is expanded. The reproducibility of the measurements is also further improved and smaller errors can be found.

According to a modified embodiment of the invention it is provided that the receiver body in the longitudinal direction, in particular along its longitudinal axis, in several Partial body is divided and / or the transmitter body in the longitudinal direction, in particular along its longitudinal axis, is divided into a plurality of partial bodies. Particularly preferably, the transmitter body is divided into several sub-bodies parallel to its longitudinal axis. A configuration of the transmitter body in the longitudinal direction with several sub-bodies increases the near resolution and the far resolution due to the controllable depth effect.

According to a particularly modified embodiment of the invention, it is provided that the receiver body is divided transversely, in particular orthogonally, to a partial body division of the transmitter body into several partial bodies. With a mutually perpendicular division of the transmitter and receiver bodies, an even better resolution, in particular at different depths, can therefore be achieved.

According to a particularly modified embodiment of the invention, it is provided that the transmitter body is divided into a plurality of sub-bodies longitudinally, in particular parallel to its longitudinal axis; and wherein the receiver body is divided into several sub-bodies transversely, in particular orthogonally, to its longitudinal axis. This allows better near and far resolution, e.g. B. be achieved with a variation of an acoustic angle. A test area is also being expanded. If the test head system is designed as a phased array, a test plan can be used to examine the sheet metal, with which the sheet metal is examined. This modified embodiment can also advantageously achieve improved receiver overlap, which enables improved test homogeneity.

According to a modified embodiment of the invention, it is provided that testing is carried out over the entire length of the test head system in small, overlapping groups of several receiver body sub-bodies smaller than a total number of elements of the receiver body sub-bodies. This increases the sensitivity with a large test track.

According to yet another particularly modified embodiment of the invention, it is provided that the transmitter body is divided into several strip-shaped partial bodies along a longitudinal direction; and the receiver body is divided into a plurality of strip-shaped partial bodies transversely to a longitudinal direction. In other words the ultrasound exit surfaces of the transmitter body are strip-shaped, that is to say elongated, and the ultrasound entry surfaces of the receiver body are strip-shaped, that is to say elongated. This enhances the advantageous effects of the modified embodiment described above.

Most preferably, the strip-shaped sub-bodies of the receiver body extend along the entire transverse direction of extent of the receiver body and the strip-shaped sub-bodies of the transmitter body extend along the entire longitudinal direction of the transmitter body. This enhances the advantageous effects of the two modified embodiments described above.

According to a modified embodiment of the invention, it is provided that the transmitter body is designed to pivot the transmitter beam angle. In particular, the phased array technique is used here. This makes testing in several zones of the workpiece advantageous.

According to a modified embodiment of the invention it is provided that a width of a partial body of the receiver body in the longitudinal direction, in particular in the direction of its longitudinal axis, is greater than a width of a partial body of the transmitter body in the transverse direction, in particular transversely to its longitudinal axis. It is particularly preferred that all partial bodies of the receiver body have the same width.

According to a modified embodiment of the invention, it is provided that the SE probe system has a control unit which is designed to control the receiver body, in particular individual partial bodies of the receiver body, for dynamic depth focusing. In other words, the individual sub-bodies can be addressed separately by the control unit. The measurement can thus be adapted to adapt to expected defects / existing dimensions in the workpiece to be tested.

According to a modified embodiment of the invention, it is provided that the SE test head system has a control unit which is designed to control the receiver body, in particular individual partial bodies of the receiver body, to one dynamic apodization. Apodization, ie weighting on individual sub-bodies, can take place, for example, in the form of targeted addressing of sub-bodies of the receiver body. This also benefits a targeted adaptation of the measuring method with the SE probe system to the properties of the workpiece.

Delay characteristics can be adjusted dynamically.

According to a modified embodiment of the invention, it is provided that the SE test head system has a control unit which is designed to control the transmitter body, in particular individual sub-bodies of the transmitter body, for dynamic apodization. An apodization, i.e. H. Weighting on individual sub-bodies can take place, for example, in the form of targeted addressing of sub-bodies of the transmitter body. This also benefits a targeted adaptation of the measuring method with the SE probe system to the properties of the workpiece.

According to a modified embodiment of the invention, it is provided that the SE probe system has a control unit which is designed to control the transmitter body, in particular individual sub-bodies of the transmitter body, to generate holographic sound fields. Holographic sound fields can be generated, for example, by specifically addressing partial bodies of the transmitter body with suitable transmitter types. Holographic sound fields advantageously make it possible to increase the test speed, in particular in combination with a paint-Bmsh method.

Brief description of the drawings

The invention is explained in more detail below with reference to the attached drawings using preferred exemplary embodiments. The formulation figure is abbreviated to figure in the drawings.

Show in the drawings Figure 1 is a schematic view of the system according to a preferred one

Embodiment of the invention;

FIG. 2 shows a schematic representation to illustrate the mode of operation of the system according to a preferred exemplary embodiment of the invention; and

FIG. 3 shows a flow diagram of a method according to a preferred one

Embodiment of the invention.

Detailed description of the working examples

The exemplary embodiments described are merely examples that can be modified and / or supplemented in many ways within the scope of the claims. Each feature that is described for a specific exemplary embodiment can be used on its own or in combination with other features in any other exemplary embodiment. Each feature that is described for an embodiment of a specific claim category can also be used in a corresponding manner in an embodiment of another claim category.

FIG. 1 shows a transmitter-receiver test head system (SE test head system) 1 according to a preferred embodiment of the invention. The system 1 has a transmitter body 2 and a receiver body 3. The transmitter body 2 and the receiver body 3 are each connected to a base body 4 which is divided into two part bodies 4a, 4b by a separating layer 5. The base body 4 has a material that is permeable to ultrasound. The separating layer 5, on the other hand, is designed as an acoustic barrier.

The transmitter body 2 and the receiver body 3 are cuboid, each with rectangular ultrasound exit and entry surfaces (not visible), via which the transmitter and the receiver body bear against the base body 4. The transmitter body 2 is divided into several sub-bodies, hereinafter referred to as the transmitter sub-body 2a. The receiver body 3 is divided into several partial bodies, hereinafter referred to as the receiver partial body 3a. The transmitter body 2 is divided into the partial bodies along its longitudinal axis. The receiver body 3 is divided into the partial bodies perpendicular to its longitudinal axis. In the present exemplary embodiment, the two longitudinal axes have a common direction of extent which runs parallel to the arrow X in FIG.

FIG. 2 shows a schematic representation to illustrate the mode of operation of the system 1 according to a preferred exemplary embodiment of the invention. Here, an area B1 is shown for possible beam courses of beams which are transmitted by the transmitter body 2. Furthermore, an area B2 is shown for possible beam courses of beams which are received by the receiver body 3. In an intersection area B3, in which areas B1 and B2 intersect, the SE test head system 1 can detect defects on a body to be tested (not shown).

The test head system 1 can be operated with a phased array (PA) electronics according to the state of the art. A combination of PA electronics with dynamic depth focusing is also possible, in particular on the receiver side, i.e. H. with the receiver body 3, possible. Dynamic apodization is also conceivable on the receiver side. The use of holographic sound fields on the transmitter side is also conceivable, i. H. at the transmitter body 2.

The SE test head system 1 according to the exemplary embodiment is suitable for testing heavy plates in a thickness range from 5 mm to 120 mm. The heavy plate test is carried out, for example, in compliance with the ISO 12094: 1994, ISO 10893-9: 2011 or ISO 17577: 2016 standards, which are only mentioned as examples.

To test a sheet, the SE test head system 1 can, for example, be moved in a meandering shape over the sheet to be tested. One or more SE probe systems 1 can be used here. A sheet metal can also be used in a system as part of the material flow, e.g. B. be checked within a production line. For example, the SE test head system 1 can be designed as a broad-beam test head in which one transmitter body 2 and four receiver bodies 3 are used. For example, the SE test head system 1 can be designed in such a way that a test width, ie a width of a workpiece that can be checked with a measuring process, of 50 mm is achieved. The signals of the individual probe systems 1 can be processed in parallel and z. B. be transmitted to an evaluation computer via a TCP / IP connection. The data evaluation can be carried out using known methods. Here, for example, the size of defects can be determined on the basis of the DIN EN ISO 16827: 2014-06 standard.

The SE probe system 1 can be operated at a frequency of, for example, 5 MHz.

The extent of a defect can be determined, for example, using the following criteria:

-6dB method: This method is advantageous in the case of inhomogeneities / imperfections, the extent of which is greater than a sound bundle

Method for amplitude evaluation based on a comparison of circular disk reflectors: This method is advantageous in the case of inhomogeneities / imperfections whose dimensions are smaller than a bundle of sound

In the case of methods that require an area to be determined for classification, neighboring test tracks must be combined to form an overall display with a corresponding extent. The summary also takes into account spatial distances between the individual inhomogeneities. For example, inhomogeneities with a sufficient distance between the depths are shown as separate inhomogeneities. In the case of elongated inhomogeneities, a width of the defect / inhomogeneity can also be determined as a further parameter via an amplitude. After the inhomogeneities have been detected, a polygon encompassing the area is calculated. An area area determined therefrom is then used for classification. FIG. 3 shows a flow chart of a method according to a preferred exemplary embodiment of the invention. The method has a method step “100”, the emission of ultrasound, over several part-body ultrasound exit surfaces of a transmitter body 2, on a sheet, as well as a method step “200” of receiving ultrasound reflected on the sheet, via several part-body ultrasound entry surfaces Receiver body 3.

Lists of reference characters

1 transmitter-receiver probe system

2 transmitter body 2a transmitter body partial body

3 receiver bodies

3 a receiver body part body

4 base bodies

4a, 4b partial body of the base body 5 separating layer

X Arrow Bl Area for ultrasonic waves from the transmitter body

B2 Area for ultrasonic waves from the receiver body

B3 cutting area

100 Radiation of ultrasound via several part-body ultrasound exit surfaces of a transmitter body onto a sheet metal

200 Receiving ultrasound reflected on the sheet metal via several partial-body ultrasound entry surfaces of a receiver body

Claims

1. Transmitter-receiver test head system, SE test head system (1), for a device for non-destructive testing of materials, comprising a transmitter body (2) with an ultrasound exit surface, designed to emit ultrasound onto a sheet metal, and a receiver body (3) with an ultrasound entry surface , designed to receive ultrasound, which is reflected on the sheet metal, and wherein the transmitter body (2) and the receiver body (3) are each divided into several sub-bodies.

2. SE probe system (1) according to claim 1, wherein the receiver body (3) is divided into several sub-bodies in the transverse direction and / or the transmitter body (2) is divided into several sub-bodies in the transverse direction.

3. SE probe system (1) according to at least one of claims 1 or 2, wherein the receiver body (3) is divided in the longitudinal direction into several sub-bodies and / or the transmitter body (2) is divided in the longitudinal direction into several sub-bodies.

4. SE probe system (1) according to at least one of the preceding claims, wherein the receiver body (3) transversely, in particular orthogonally, to a

Part-body division of the transmitter body (2) is divided into several part-bodies.

5. SE probe system (1) according to at least one of the preceding claims, wherein the receiver body (3) transversely, in particular orthogonally, to a

The longitudinal direction is divided into several partial bodies; and wherein the transmitter body (2) is divided into a plurality of partial bodies longitudinally, in particular parallel, to a longitudinal direction.

6. SE probe system (1) according to at least one of the preceding claims, wherein the receiver body (3) is divided transversely to a longitudinal direction into a plurality of strip-shaped partial bodies; and wherein the transmitter body (2) is divided into a plurality of strip-shaped partial bodies along a longitudinal direction.

7. SE probe system (1) according to at least one of the preceding claims, wherein a width of a partial body of the receiver body (3) in the longitudinal direction is greater than a width of a partial body of the transmitter body (2) in the transverse direction.

8. SE test head system (1) according to at least one of the preceding claims, comprising a control unit configured to control the receiver body

(3), in particular individual partial bodies of the receiver body (3), for dynamic depth focusing.

9. SE test head system (1) according to at least one of the preceding claims, comprising a control unit configured to control the receiver body

(3), in particular individual partial bodies of the receiver body (3), for dynamic apodization.

10. SE probe system (1) according to at least one of the preceding claims, having a control unit configured to control the transmitter body (2), in particular individual sub-bodies of the transmitter body (2), for generating holographic sound fields.

11. Device for testing sheet metal, having at least one SE test head system (1) according to at least one of the preceding claims.

12. Procedure for non-destructive testing of materials, comprising the following procedural steps:

Radiation of ultrasound (100) via several part-body ultrasound exit surfaces of a transmitter body (2) onto a metal sheet;

Receiving ultrasound (200) reflected on the sheet metal via a plurality of partial-body ultrasound entry surfaces of a receiver body (3); or having method steps corresponding to features of an SE test head system (1) according to at least one of the preceding claims.

13. Computer program, comprising instructions which, when the computer program is executed by a computer, cause the computer to carry out a method according to the preceding claim.

14. Data carrier signal which the computer program transmits according to the preceding claim.

15. A computer readable medium comprising instructions which, when executed by a computer, cause the computer to carry out a method according to claim 12.