Engraving device and method for creating and measuring stress corrosion cracking on a flat coated test specimen

The invention claimed is: 1. A method for creating and measuring stress corrosion cracking on a flat coated test specimen ( 1 ) which has a basic body ( 11 ) with a basic body surface ( 9 ) and, applied thereto, a layer system ( 5 ) with a boundary surface ( 14 ) adjoining the basic body surface ( 9 ), the method comprising the following steps: introducing a mechanical load into a test specimen surface ( 2 ) of the layer system ( 5 ) using a rotating engraving head ( 3 ) of an engraving device ( 4 ), wherein the engraving head ( 3 ) at least partially penetrates into the layer system ( 5 ) with a constant pressing force and at a constant rotational speed; moving the rotating engraving head ( 3 ) along the test specimen surface ( 2 ) and relative to the test specimen ( 1 ) at a constant movement speed in order to create at least one engraving ( 6 ) on the test specimen surface ( 2 ) by plastic deformations and/or brittle chipping of the layer system ( 5 ); and measuring the at least one engraving ( 6 ) introduced into the test specimen surface ( 2 ) by a light-optical method for evaluating the layer adhesion of the layer system ( 5 ) on the basic body ( 11 ). 2. The method as claimed in claim 1 , characterized in that the pressing force and the rotational speed of the engraving head ( 3 ) are monitored and controlled by a control unit ( 7 ). 3. The method as claimed in claim 2 , the method further comprising at least partially covering the surface ( 2 ) of the test specimen ( 1 ) with a corrosive medium in order to accelerate a stress corrosion cracking of the test specimen ( 1 ) by local delaminations between the layer system ( 5 ) and the basic body ( 11 ) of the test specimen ( 1 ); wherein the measuring the at least one engraving ( 6 ) introduced into the surface ( 2 ) of the test specimen ( 1 ) by the light-optical method for evaluating the layer adhesion of the layer system ( 5 ) on the basic body ( 11 ) is after the acceleration of the stress corrosion cracking. 4. The method as claimed in claim 1 , the method further comprising at least partially covering the test specimen surface ( 2 ) with a corrosive medium in order to accelerate a stress corrosion cracking of the test specimen ( 1 ) by local delaminations between the layer system ( 5 ) and the basic body ( 11 ) of the test specimen ( 1 ); wherein the measuring the at least one engraving ( 6 ) introduced into the test specimen surface ( 2 ) by the light-optical method for evaluating the layer adhesion of the layer system ( 5 ) on the basic body ( 11 ) is after the acceleration of the stress corrosion cracking. 5. An engraving system ( 4 ) for creating and measuring stress corrosion cracking on a flat coated test specimen ( 1 ) which has a basic body ( 11 ) with a basic body surface ( 9 ) and, applied thereto, a layer system ( 5 ) with a boundary surface ( 14 ) adjoining the basic body surface ( 9 ) comprising: a three dimensionally movable sample table ( 10 ) for receiving the test specimen ( 1 ), a rotatable engraving head ( 3 ) configured to load the test specimen ( 1 ) with a defined pressing force and at a defined rotational speed and to create an engraving ( 6 ) in a surface ( 2 ) of the test specimen ( 1 ), a light microscope ( 12 ) configured for light optical measurement and evaluation of the engraving ( 6 ) introduced into the surface ( 2 ) of the test specimen ( 1 ), and a control unit configured to: cause the rotatable engraving head ( 3 ) to introduce a mechanical load into the surface ( 2 ) of the layer system ( 5 ) to at least partially penetrate into the layer system ( 5 ) with a constant pressing force and a constant rotational speed, cause the three dimensionally movable sample table ( 10 ) and the rotatable engraving head ( 3 ) to move the rotating engraving head ( 3 ) along the surface ( 2 ) of the test specimen ( 1 ) and relative to the test specimen ( 1 ) at a constant movement speed in order to create at least one engraving ( 6 ) on the test specimen surface ( 2 ) by plastic deformations and/or brittle chipping of the layer system ( 5 ), and cause the light microscope ( 12 ) to measure the at least one engraving ( 6 ) introduced into the test specimen surface ( 2 ) by a light-optical method for evaluating the layer adhesion of the layer system ( 5 ) on the basic body ( 11 ). 6. The engraving system ( 4 ) as claimed in claim 5 , characterized in that the engraving head ( 3 ) has a diamond coating. 7. The engraving system ( 4 ) as claimed in claim 5 , characterized in that the engraving head ( 3 ) is spherical. 8. The engraving system ( 4 ) as claimed in claim 5 , characterized in that the engraving head ( 3 ) is disk-shaped. 9. The engraving system ( 4 ) as claimed in claim 5 , wherein the three dimensionally movable sample table ( 10 ) is configured to be movable in a desired direction in a table plane so as to create the at least one engraving ( 6 ). 10. The engraving system ( 4 ) as claimed in claim 5 , wherein the engraving head ( 3 ) is configured to be to be movable three dimensionally in order to be guided over the surface ( 2 ) of the test specimen.