DE19712650C2 - Procedure for crack testing of highly stressed components - Google Patents

Description

The invention relates to a method for checking construction share on defects, especially for crack testing, as in The preamble of claim 1 is assumed.

For checking components, which special loads subject and therefore he special reliability criteria crack tests are applied. For use come mainly the dye penetration test and the Eddy current testing. In the color penetration test, the total te component surface treated with a coloring agent and on cracks indicated by increased accumulation of the colorant evaluated. In the case of hidden cracks or one This test ver is the unfavorable condition of the component surface but cannot be used. During the eddy current test the component surface to be tested using an eddy current probe de meandering or circularly scanned, one possible wise existing crack detected by a typical measurement signal becomes. If the component geometry is complicated, the guide is the Eddy current probe, however, very expensive or it is through geometrically confined conditions on the component a movement of the Probe even impossible.

Compressor blades and compressor disks of turbines, esp Especially jet engines are among the mechanically high ones stressed components where a crack leads to component failure and can cause catastrophic damage. For those at risk of cracking Areas on the turbine disc bumps and the compressor Bucket feet are the two test methods mentioned above not suitable, because the component geometry limits the on  and the routing of eddy current probes to subareas and the fretting that occurs at the highly stressed areas (Frictional wear) with the material used as standard Titan is preventing the use of the dye penetration test the most critical spots.

In the present invention, a method for checking is provided Testing components for defects, especially for crack testing known provided that an ultrasonic wave is generated and the component is exposed to the ultrasonic wave, and a wave reflected from a defect present on the component is detected to detect the defect.

In "Material testing with ultrasound", J. Krautkrämer, H. Krautkrämer, 5th edition, 1986, pages 390 to 391 a Ver drive to check components for cracks, where the area of the component to be checked with a plastic block is brought into contact and one in the plastic block Ultrasonic wave is generated. Cracks in the Be range of the component detected by the plastic block around give is.

The US 52 75 052 shows an ultrasonic test system with which an Ul ultrasound beam to a spot on the surface of an over testing component is directed. Of the. Beam is through a Liquid passed and to the surface of the in the liquid coupled immersed component.

DE 43 05 064 C1 describes a method and a device for simultaneous non-destructive characterization of several Characteristic values of surface-modified materials are described. There at become from the waveform of two ultrasound surface wave impulses cut out frequency ranges because  out run times and speeds determined and corrected the characteristic value determined.

In the known methods there is a risk that fretting or friction wear marks in the area of the crack its detection hinder or generate interference signals, making the Reliable speed and the sensitivity of detection is impaired.

It is the object of the present invention, a method To check components for defects, indicate the one offers increased reliability and also in critical areas a high detection sensitivity, e.g. B. in the crack test, having.

This object is achieved by the method specified in claim 1 solved.

According to the invention, a method for checking construction share indicated for defects, especially for crack testing which generates an ultrasonic wave and the component of the Ultra sound wave is exposed and one of one on the component existing defect reflected wave to detect the defect is detected, a first area of the item to be checked Component is brought into contact with a first medium, and an ultrasonic wave is generated in the first medium, and the component in a second area on the defect un is examined, wherein the second area from a second medi around and from the interface between the first me dium and the second medium a surface wave on the top surface of the component runs into the second area and then ßend one of the defects present in the second area tated wave is detected.  

A major advantage of the method according to the invention is it exists in the second area to be examined Fretting marks (wear marks) the detection of cracks  do not hinder and do not normally generate an interference signal. Thus, a high detection sensitivity and a high Detection reliability achieved. Another advantage of The inventive method is that even hidden cracks are detectable in the second area to be examined.

According to an advantageous embodiment of the invention The method provides that the reflection from the defect tated wave as surface wave back into the first medium runs and is detected there.

According to an embodiment, it is provided that the first medium is a liquid and that the second medium is a gas. In particular, it is advantageous if the first medium is water is and the second medium is air.

According to an advantageous embodiment of the invention The method provides that the ultrasound wave is by means of one immersed in or attached to the first medium pelten ultrasonic transducer is generated.

The wave reflected by the defect is preferably by means of of the ultrasonic transducer generating the ultrasonic wave animals. Alternatively, the one reflected by the defect can be Wave immersed in the first medium by means of another or who is connected to this coupled ultrasonic transducer the.

It is preferably provided that the surface of the component is scanned in a spatially resolving manner by means of the ultrasonic wave. It can be provided that the surface of the component by shifting the component and the ultrasonic transducer relatively to each other is scanned in a spatially resolving manner, or alternatively can the surface of the component using an ultrasonic transducer be scanned locally, which is an ultrasonic wave variable direction. It is preferably pre-selected hen that the surface of the component of the cutting line of the upper  area of the same and the interface of the first and second Medium is scanned following.

The component to be examined preferably becomes only one small part immersed in the first medium. This has the Advantage that the surfaces generated by the ultrasonic wave wave immediately after the coupling of the liquid leaves the area. Sound losses through radiation and In this way, friction is kept to a minimum.

It is of particular advantage to have the interface at the surface surface of the first medium using a thin film and the component to be examined over this thin film with the to bring the first medium into contact. This will make the influence of wave movements of the liquid and capillary sutures underneath presses so that a further reduction of the interference signal and a Increase in detection sensitivity can be achieved. The The film is preferably a plastic film.

The use of the invention is particularly advantageous Procedure for checking construction that is heavily loaded during operation parts made of metal, with the checked parts in particular Titan can exist.

The Ver according to the invention proves to be particularly advantageous drive to check compressor blades and / or Ver sealing discs of turbines, in particular of jet engines ken and gas turbines.

The method according to the invention is particularly advantageous for Checking the blade roots of compressor blades and / or the disc hump of compressor discs, these on one first, in the area with little traffic, with the first Medium to be contacted to a second, in operation highly stressed area of the blade root or the disc hump kers for defects, especially for cracks.

The following is an embodiment of the invention Process explained using the drawing.

The figure shows an arrangement for examining a blade foot or disc hump of a compressor blade or one Compressor disk of a turbine according to an embodiment the invention.

In the figure, reference numeral 1 denotes a component to be checked, for example the blade root of a compressor blade or the disc hump of a compressor disc. In the component 1 to be examined there is a first region 1 a on the lower, flat region of the blade root and a second region 1 b on the side of the component to be examined, in which large forces act in the operating state of the component and thus high loads occur. Due to the friction wear that occurs in the process, so-called fretting marks (friction wear marks) are formed in the second area 1 b. This second area 1 b is at the same time the area of the component 1 to be examined for existing defects, in particular cracks, a crack 4 being shown in the figure in the second area 1 b. Such a crack 4 , if it remains undetected during the examination of the component, could have catastrophic consequences during operation and must be reliably identified.

To check the component 1 for defects, in particular a crack 4 , the first region 1 a, here namely the lower, flat region of the blade root or the bump of the disc, is brought into contact with a first medium 2 , in which an ultrasonic transducer 3 is arranged is that emits an ultrasonic wave 7 in the direction of the first region 1 a. The rest of the component 1 to be examined above the first medium 2 is surrounded by a second medium 9 . In the exemplary embodiment, the first medium 2 is water and the second medium 9 is air.

Between the underside of the blade root or the disc hump, the first area 1 a, and the surface of the water bath 2 , a plastic film 6 is arranged which has an interface 8 between the first area 1 a of the component 1 to be examined and the first medium 2 , the water bath forms. The water plastic film suppresses the influence of wave movements in the water bath 2 and capillary seams.

To check the component for defects, in particular cracks, an ultrasonic wave 7 is generated with the ultrasonic transducer 3 and in the vicinity of the cutting line of the surface of the construction part 1 and the interface 8 of the first and second medium 2 , 9 on the first region 1 a emitted. Here, the ultra sound wave 7 is coupled into the first area 1 a of the component 1 and runs as a surface wave 5 following the surface contour of the component 1 into the area 1 b to be examined. A defect present in this area, such as the crack 4, generates an echo signal in the form of a reflected wave, which runs back into the water bath 2 in the opposite way and can be detected there. In the second region 1 b on the upper surface of the existing component to be examined Frettingmarken normally lead to any disturbing signal, so that the reconsider a component with a high detection sensitivity is performed.

The reflected wave from the crack 4, also returning as a surface wave into the water bath 2 , is detected again in the water bath by means of the ultrasonic transducer 3 . As an alternative to this, a further ultrasonic transducer 11 can also be provided, which is used to record the reflected signals.

For the spatially resolving scanning of the surface of the component 1 , the component 1 and the ultrasound transducer 3 are displaced relative to one another or an ultrasound transducer 3 is used which emits an ultrasound wave 7 of variable direction. The surface of the component 1 is scanned following the cutting line from its upper surface contour and the boundary surface 8 , that is to say in the area where the component 1 is still in the water bath 2 .

With the method according to the invention can be high in operation loaded parts, especially engine parts such as blade feet  of compressor blades and disc humps of compressor discs ben reliably and with high sensitivity to detection on De defects, especially for cracks.

Claims (18)

1. A method for checking components for defects, in particular for crack testing, in which an ultrasonic wave ( 7 ) is generated and the component ( 1 ) is exposed to the ultrasonic wave ( 7 ) and one of a defect on the component ( 1 ) is present ( 4 ) reflected wave for detecting the defect ( 4 ) is detected, wherein
a first region ( 1 a) of the component to be checked ( 1 ) is brought into contact with a first medium ( 2 ), and
an ultrasonic wave ( 7 ) is generated in the first medium ( 2 ),
characterized by
that the component ( 1 ) is searched for in a second area ( 1 b) for the defect ( 4 ), the second area ( 1 b) being given by a second medium ( 9 ) and by the interface ( 8 ) between the first medium ( 2 ) and the second medium ( 9 ) a surface wave ( 5 ) on the surface ( 10 ) of the component ( 1 ) in the second area ( 1 b) and then
a wave reflected by the defect ( 4 ) present in the second region ( 1 b) is detected. 2. The method according to claim 1, characterized in that the wave reflected by the defect ( 4 ) runs back as a surface wave in the first medium ( 2 ) and is detected there. 3. The method according to claim 1 or 2, characterized in that the first medium ( 2 ) is a liquid and that the second medium ( 9 ) is a gas. 4. The method according to claim 3, characterized in that the first medium ( 2 ) is water and that the second medium ( 9 ) is air. 5. The method according to any one of claims 1 to 4, characterized in that the ultrasonic wave ( 7 ) by means of an immersed in the first medium ( 2 ) or coupled to this ultrasonic transducer ( 3 ) is generated. 6. The method according to claim 5, characterized in that the from the defect ( 4 ) reflected wave by means of the ultrasonic wave Ul ( 7 ) generating ultrasonic transducer ( 3 ) is detected. 7. The method according to claim 5, characterized in that the from the defect ( 4 ) reflected wave is immersed by means of a wide ren in the first medium ( 2 ) or coupled to this ultrasonic transducer ( 11 ). 8. The method according to any one of claims 5 to 7, characterized in that the surface of the component ( 1 ) by means of the ultrasonic wave ( 7 ) is scanned in a spatially resolving manner. 9. The method according to claim 8, characterized in that the surface of the component ( 1 ) by displacement of the component ( 1 ) and ultrasonic transducer ( 3 ) relative to each other is scanned in a location-resolving manner. 10. The method according to claim 8, characterized in that the surface of the component ( 1 ) by means of an ultrasound transducer ( 3 ) is scanned in a spatially resolving manner, which emits an ultrasonic wave ( 7 ) of variable direction. 11. The method according to any one of claims 8 to 10, characterized in that the component ( 1 ) is scanned following the cutting line of the surface of the component ( 1 ) and the interface ( 8 ) of the first and second medium ( 2 , 9 ). 12. The method according to any one of claims 3 to 11, characterized in that the component to be examined ( 1 ) is partially immersed in the first medium ( 2 ). 13. The method according to any one of claims 3 to 11, characterized in that the interface ( 2 ) on the surface of the first medium ( 2 ) is generated by a thin film ( 6 ), and that the component to be examined ( 1 ) on the thin film ( 6 ) with the first medium ( 2 ) is brought into contact. 14. The method according to claim 13, characterized in that the film ( 6 ) is a plastic film. 15. The method according to any one of claims 1 to 14, characterized in that the component ( 1 ) is made of metal. 16. The method according to claim 15, characterized in that the component ( 1 ) consists of titanium. 17. The method according to claim 15 or 16, characterized in that the construction part ( 1 ) is a compressor blade and / or a compressor disk of a turbine, in particular a jet engine and a gas turbine. 18. The method according to claim 17, characterized in that for checking the blade roots of compressor blades and / or bumps of compressor discs, these are brought into contact with the first medium ( 2 ) at a first area ( 1 a) which is slightly loaded during operation to examine the second area ( 1 b) of the blade root or the bump of the disc, which is highly loaded during operation, for defects, in particular for cracks.