DE3409011A1 - Metallographic examination method and clamping frame for carrying it out - Google Patents

Abstract

Metallographic examination method for imaging sample surfaces, prepared by grinding, polishing, possibly etching, cleaning and drying, on structural elements that are to be examined for defects and microstructure by means of a replica foil (f) of appropriate size which is coated with a replication agent, in particular triacetate, and before replication is moistened on its coating side (f2) by means of a softening agent - in particular, acetone in the case of a triacetate foil - and then laid with the coating side onto the sample surface, and is pressed for a prescribed time against said sample surface in a manner as free from bubbles as possible and is left thereon to fix the image, after which the replica foil is removed from the sample surface and subjected to a macroscopic/microscopic and/or photographic evaluation. After removal from the sample surface, the replica foil (f) is laid on the lower part (R1) of a clamping frame (R), which surrounds the image of the replica foil, with the coating side (f2) upwards and with an appropriate edge overlap (f0). The upper part (R2) of the clamping frame (R) is then pushed with its inner circumference (m20) over the outer circumference (m10) of the lower part (R1) and over the edge overlap (f0) of the replica foil (f) laid around in the process, this being done with a snug fit in such a way that the replica foil is clamped on the clamping frame (R) in the manner of an embroidery frame clamping with a smooth, stressed surface of its coating side (f2). <IMAGE>

Description

Metallographic examination method and tensioning

men for its implementation. The invention relates to metallographic Examination method for the mapping of grinding, polishing, if necessary, pitting, Cleaning and drying prepared test surfaces for defects and structure examined components by means of an impression agent, in particular triacetate, coated impression film of a corresponding size, according to the preamble of the claim 1.

Such an investigation procedure is of particular importance for the so-called outpatient metallography on components of machine and apparatus construction on site in the power plant or in the factories. It is often necessary to make a metallographic cut directly on the metal body of the component. An impression must be taken so that it can be examined under laboratory conditions will. Previous methods of taking impressions are not satisfactory and leave one Examination and assessment at magnifications of over 250: 1 are not permitted. Under outpatient As in the following, metallography is a non-destructive microsection examination understood on the components outside the laboratory.

The task at hand is the metallographic examination method of the type defined in the preamble of claim 1 to be improved so that also microscopic and / or photographic evaluations are made possible, which a Allow more than 250x magnification. In particular, enlargements should be at least the impression obtained from the impression film to 500: 1 and possibly still be possible about it.

According to the invention, the task at hand is achieved with a metallographic Examination method of the type mentioned at the beginning by the method indicated in the identifier of the Claim 1 specified features solved. An advantageous embodiment of this The method relates to claim 2.

The invention also relates to a tenter frame for implementation of the generic examination method as stated in claim 3 in the main and is characterized with further refinements in claims 4 to 6.

The advantages that can be achieved with the invention are above all in this too see that due to the high quality of the images obtained, outpatient Microsection examinations under laboratory conditions up to magnifications of 500: 1 and possibly carry out over it and document it photographically with good quality permit. Clamping the impression film in the clamping frame is quick and easy in front of you, as well as the removal from the stenter. The slide can then be used in one Glassless slide frames can be kept and can be viewed at any time under the microscope regard. The smooth surface obtained by the stenter also remains Get clamped in a slide frame.

In the following, the invention is illustrated by means of one in the drawing Embodiment for the clamping frame and several imprint examples in different Scales explained in more detail. In the drawing: Fig. 1 shows the dismantled Tenter frame with its lower and upper part and one in between indicated imprint film in plan view; Fig. 2 is a perspective view of the Clamping frame with clamped impression film; FIGS. 3 to 8 are photographs of impressions obtained with a method according to the invention, namely Fig. 3 on a scale of 500: 1 a section of the surface of a turbo generator cap of the material X 55 MnCr 18 K, whose austenitic mixed grain material is transcrystalline Has stress cracks; 4 shows the image of the surface section, also on a scale of 500: 1 a pot housing made of the material GS 17 CrMoV 511, with a manufacturing defect with internal oxidation is recognizable (scaled cracks or defects are in the film impression white and not gray as in the micrograph); Fig. 5 as well as in Figs. 3 and 4 the Imprint obtained with a triacetate film, as a photographic enlarged a hundred times Illustration of the cross-section of a turbine blade made of the material X20Cr 13; 6 shows the object according to FIG. 5, but enlarged five hundred times; 7 shows an impression of the same micrograph as in FIGS. 5 and 6, however obtained with a triacetate foil coated with gold, and FIG. 8 shows the object according to Fig. 7, but magnified five hundred times.

The clamping frame R shown in Fig. 1 consists of a lower part R1 and an upper part RQ. Both parts R1, Rb2 are ring-shaped and each have a shell part ml or m2 and one connected to the respective shell part Ring collar k1 or k2. The inner diameter D2 of the upper frame R2, i.e. H. the diameter of its inner circumference m20 is slightly larger than the outer diameter D1 of the lower frame R1, i. H. the diameter of its outer circumference m10. In In a version for larger prints, the dimensions in mm were: D1 = 42, D2 = 42.5. The wall thickness wl of the lower frame R1 and w2 of the upper frame R2 was 2 mm each. In a version for smaller prints, the values (in mm) : Dl '= 31, D2' = 31.5, wl = w2 = 1.5. In both versions, the height was hl des Shell part ml = 8 mm and the height h2 of the shell part m2 = 5.5 mm.

The one shown between the lower and upper frames R1, R2 Foil f has a thickness of about 0.1 mm; she is on one side f2, which facing the upper frame R2, provided with a triacetate layer and consists made of a suitable flexible plastic.

Such triacetate films are z. B. from Coloprint at under the trade name Triazol.

In principle, there are also other methods for the method according to the invention Films suitable, but the best results were achieved with triacetate films.

For the illustration according to FIG. 1 it is assumed that the impression film f has already been removed from a test area. It will then, as shown, on the lower part Rl of the tenter frame framing the image of the impression film f R with its layer side f2 upwards and placed with the corresponding edge overhang fO.

Then the upper part R2 of the spami frame R with its inner circumference m20 over the outer circumference m10 of the lower part R1 and the overlapping edge overhang fO of the impression film f pushed with a snug fit in such a way that the impression film f after Type of an embroidery frame clamping on the tenter frame R with a smooth, taut surface its layer side f2 is clamped, as shown in FIG.

This results in shearing or damage during this clamping process the imprint film f cannot take place, are the mutually facing, the edge overhang fO of the impression film f contacting ring end faces m11 and m21 as well as the associated Outer circumferential surfaces m10 or

Provide m22 with rounding radii rl or r2. A suitable rounding radius i. e.g. 0.8 mm. At the points 1 of the upper frame R2 additional could Rounding radii may be provided (not shown).

The difference in diameter D2 D1 and thus the gap width between the outer circumference m10 of the lower frame R1 on the one hand and the inner circumference m20 of the upper frame R2 on the other hand is chosen so that taking into account the strength the imprint film f this when join the frame parts R1, R2 can be clamped and smoothed effortlessly and does not slip when clamped. On the other hand, a dismantling of the two frame parts should be done without great effort be made possible.

In the exemplary embodiment shown, the gap width was approx. 0.25 mm, so that foils of about 0.1 mm thickness are clamped with such a tenter frame can be; taking into account the folds is the thickness of the impression film about 10 to 15 hundredths of a mm smaller than the gap width.

When the upper frame R2 is pushed completely over the lower frame R1 is, then the ring face mll of the latter looks over a little bit the ring collar k2 because hl is greater than the sum of h2 and the strength from k2. The film from the shell part m2 of the upper frame 2 is against the lower Stop surface k10 of the ring collar kl of the lower frame R1 pressed.

This fully assembled state is convenient with a Achieved press that is evenly adjustable with a small pressure, for example by means of a handwheel, after the clamping frame R with the inserted impression film f is initially put together about halfway by hand. So that the tensioning frame R in the assembled state against unintentional loosening or dismantling is fixed, it can be advantageous on the facing end faces of the Ring collar kl, k2 holding magnets and jacking screws at other circumferential locations to arrange. Another fixation option, which is also not shown, would be the one, the ring collar kl, k2 with a wreath of at least 3 around the circumference evenly distributed threaded holes and associated, stored in the other frame part Screws to be provided.

The impression film clamped in according to FIG. 2 can then be of a macroscopic, microscopic and / or photographic evaluation in a metal testing laboratory will.

The transport there is without damaging the abduct / stenter frame easily possible. There are no signs of distortion when tensioning lower and upper frame R1, R2 of the clamping frame R preferably made of a dimensionally stable Metal. Stainless steel is suitable for this. A preferred material is brass. if also generally clamping frames with rectangular or circular shapes Plan are possible, so have circular ring bodies for the frame parts Rl, R2 proved to be particularly favorable.

3 through 8 are enlarged photographs of the print image of impression foils clamped in the tenter frame according to FIG. 2. About the prints to win, the sample area on the metal body to be examined for defects initially prepared by grinding, polishing, possibly etching, cleaning and drying. Grinding takes place up to grain size 1000, diamond paste is used for the subsequent polishing 3im and clay used.

For the impression according to FIG. 3, the test surface was also etched made of the examined cap with a 5% aqueous nitric acid HIN03. The impression film was on the layer side, i.e. H. the shiny, with triacetate coated side, drizzled with acetone and then with the clean fat-free Press your thumb on the cleaned and dried sample surface for about 15 seconds. Then the impression film was applied approx.

Leave on the sample area for 2 minutes. When pressing the impression film the formation of bubbles must be avoided. After carefully peeling off the impression film this is then with the layer side f2 facing up the lower part R1 (see Fig. 1) of the tenter frame R laid. The further procedural steps are then as already explained. The imprint which was used for the recording according to Fig. 3 on a scale of 500: 1 was made on site on a generator rotor cap. Small dust particles can be seen, but they do not hinder the evaluation. The sharp image at the selected scale is remarkable.

The imprint on which the illustration according to FIG. 4 (scale 500: 1) is based was produced dust-free in the laboratory using the methods described above Procedural steps. The impression was taken from the cross-section of a pot housing. The polished section was again etched with 5% aqueous HIN03.

The same process steps for taking an impression as in the first and second example according to FIG. 3 or

4 using a triacetate film were carried out on the further two examples according to FIGS. 5 to -8, which imprints of a cross-section on a turbine blade.

FIGS. 5 and 6 show the photographic image of the impression of a Triacetate film on a scale of 100: 1 (Fig. 5) and 500: 1 (Fig. 6). It should be emphasized the sharpness of the image according to FIG. 6.

If necessary, the contrast can be increased by using a triacetate film can be achieved, which is subsequently vaporized with gold after the impression has been taken. the The figures obtained are shown in FIG. 7 (scale 100: 1) and FIG. 8 (scale 500: 1). That is to say, the test surface that had a tempered structure (tempered martensite) and was etched with picrine hydrochloric acid, in the third example according to Fig. 5 and 6 are the same as in the fourth example according to FIGS. 7 and 8.

The shelf life of the treated by the method of the invention Impression foils have already been observed in the laboratory over a period of around 2 years been; so far there have been no changes.

The particular advantage of the method and the stenter after the Invention consists in the fact that not only can work be carried out non-destructively, but also a transport of heavy components to the laboratory or of larger laboratory equipment can be omitted for the component. The imprint, especially in its 500 times enlarged In many cases, an image is sufficient to assess material imperfections on the light microscope the end.

6 claims 8 figures - space -

Claims (6)

Claims 9 metallographic examination method for imaging of prepared by grinding, polishing, possibly etching, cleaning and drying Test areas on components to be examined for defects and structure by means of a corresponding impression film coated with an impression agent, in particular triacetate Size, which before taking the impression on its layer side with an emollient - in the case of a triacetate film, especially acetone - moistened and then with the layer side is placed on the test surface, as well as a predetermined time against this Pressed as bubble-free as possible and left on this to fix the image is, after which the impression film is peeled off the sample area and a macro / microscopic and / or is subjected to photographic evaluation, d u r c h e k e n n -z e i c h n e t that the impression film (f) appears after it has been peeled off from the sample area the lower part (R1) of a span frame framing the image of the impression film (R) with the layer side (f2) upwards and with the corresponding edge overhang (fO) is placed, and that the upper part (R2) of the clamping frame (R) with its inner circumference (m20) over the outer circumference (m10) of the lower part (R1) and the surrounding area Edge overhang (fO) of the Abiruckfolie (f) is pushed with a snug fit so that the Impression film in the manner of an embroidery frame clamping on the clamping frame (R) with a smooth, tensioned surface of its layer side (f2) is clamped. 2. The method of claim 1, d a d u r c h g e -k e n n z e i c h n e t that the tensioning frame (R) with the imprint film (f) inserted is initially halfway from Hand and then with a press with a small stroke per unit of time is fully compressed to a stop. 3. Tenter frame for performing the method according to claim 1 or 2, d u r g e k e k e n n -z e i c h n e t, that his lower and his upper part (R1, R2) consist of ring bodies, whose outer surfaces (m10, m20) on the outer circumference of the lower part (R1) and one on the inner circumference of the upper part (R2) Difference in diameter or gap width matched to the thickness of the impression film (f) have and their facing, the edge overhang (fO) of the impression film (f) contacting ring end faces (with, m21) with rounded edges (r1, r2) are provided. 4. Tenter frame according to claim 3, d a d u r c h g e -k e n n z e i. c h n e t that the ring bodies (R1, R2) are made of metal. 5. Tenter frame according to claim 4, d a d u r c h g e -k e n n z e i c h n e t that the ring bodies (R1, R2) are made of brass. 6. Tenter frame according to one of claims 3 to 5, d a -d u r c h g It is clear that the ring bodies (R1, R2) are circular ring bodies.