CH705517A2 - Specimen for Werkstoffprüfvorrichtung. - Google Patents

Abstract

Disclosed is a test specimen for use in a material testing device. The test specimen has a specimen holder (12) which is designed for the purpose of attachment to the Werkstoffprüfvorrichtung. The test specimen holder (12) carries a test specimen tip (10). The test piece tip (10) is coated with a mass of ceramic binder (14), such as e.g. a binder made of cured soluble silicate attached to the test specimen holder. The specimen tip (10) may be supported on a flat surface of the specimen holder (12), in a recess (28) of the specimen holder, or in a space in the specimen holder.

Description

The present invention relates to a suitable for use in a Werkstoffprüfvorrichtung test specimen and a device containing such a specimen.

Impressive and Kratzversuche of materials are generally carried out using a relatively hard specimen, which is either pressed under constant or variable load in a surface or pulled over a surface. Test specimens usually have a tip made of diamond or ceramic crystals ground and polished to a defined geometry and a holder supporting the tip. The holder is designed to be suitable for use with the testing device, e.g. the device disclosed in EP-A-1 095 254 of the present applicant.

For experiments at room temperature or at moderate temperatures, the crystal can be securely attached to a holder by means of a polymer adhesive or a metal solder. Polymers are generally unsuitable above about 100 ° C or in some chemically aggressive atmospheres because they usually soften or eventually decompose under such conditions. Brazing alloys can safely be used up to higher temperatures, usually up to about 400 ° C, but various solder components tend to react or evaporate with atmospheric gases as the temperature is further increased. Evaporation causes contamination of the tip of the specimen and a specimen positioned adjacent the tip of the specimen. The evaporation is therefore problematic both in the air and in a vacuum.

An object of the invention is to provide a specimen that can be used at elevated temperatures without having the disadvantages of conventional specimens.

For this purpose, the invention provides in a first aspect a test specimen for use in a Werkstoffprüfvorrichtung according to claim 1.

Since the present invention provides a ceramic bond between the tip of the specimen and its holder, it can be used without risk and significantly beyond the temperature range available for conventional specimens, both in air and in vacuum, without any To experience material deterioration.

The workpiece tip is usually made of a piece of hard crystalline material, e.g. Diamond or crystalline ceramics. Alternative materials may be chosen which are suitable for specific situations, such as e.g. Sapphire or cubic boron nitride. The workpiece tip is most typically ground and polished to a predetermined shape and dimension.

The binder is preferably of a type which is chemically cured instead of by evaporation. It is chosen to have refractory properties. The binder may include a soluble silicate and may specifically be a cured mixture of sodium silicate or potassium silicate and zirconium silicate.

The test specimen tip may be mounted on a flat surface of the specimen holder or in a recess formed in the specimen holder. Alternatively, the test specimen tip may be located in a space in the specimen holder and arranged to protrude from the specimen holder. In such embodiments, the binder occupies a volume surrounding the probe tip in the space. Embodiments of this type allow the mechanical positioning of the tip in the tip holder to supplement the action of the binder.

The specimen holder may be made of stainless steel, other metals such as molybdenum, alloys such as austenitic nickel-chromium based superalloys, e.g. Inconel (rtm), or be made of a refractory material.

In a second aspect, the invention provides methods for producing a test specimen according to the first aspect of the invention as set out in claim 8 or claim 9. In either case, the method may further include forming the test specimen tip to the desired shape and dimensions. In molding the test specimen tip to the desired shape and dimensions, both the crystal and the binder may be subjected to a process involving grinding and / or polishing. The complete curing of the binder is usually achieved as a final step by heating the specimen to a temperature close to the maximum operating temperature of the specimen and in a suitable atmosphere, e.g. to a temperature of about 750 ° C in the preferred embodiment.

In a third aspect, the invention provides a material testing device that includes a test specimen that embodies the first aspect of the invention.

In a fourth aspect, the invention provides a material test method as set forth in claim 13.

In a method embodying this aspect of the invention, the test specimen and / or the specimen can be heated. The temperature to which he or she is heated may be above 100 ° C and may exceed 500 ° C.

Embodiments of the invention will now be described in detail by way of example with reference to the accompanying drawings. <Tb> FIG. 1 and 2 <sep> are cross-sections of test specimens which are a first and a second embodiment of the invention, respectively. <Tb> FIG. FIG. 3 shows a pusher tool used in manufacturing the embodiment of FIG. 6. FIG. <Tb> FIG. 4 <sep> shows in cross section a first step in the production of the test body of FIG. 6. <Tb> FIG. 5 <sep> shows in cross-section a second step in the manufacture of the test specimen of Fig. 6und <Tb> FIG. Fig. 6 <sep> shows in cross section a third embodiment of the invention.

An inventively ausgestaltender test body shown in FIGS. 1 and 2 has a tip 10 which is supported by a Prüfkörperhalter 12, to which it is attached with binder 14. In these embodiments, the tip 10 is held in place only by the binder 14.

In the embodiment of Fig. 1, the test body holder 12, which is made of a block of stainless steel, a cylindrical body piece 20 and a coaxial with the cylindrical body piece 20 head piece 22, which is designed as a truncated cone with a flat mounting surface 24 , The axis of the cylindrical body piece 20 is usually perpendicular to the mounting surface 24th

The embodiment of FIG. 2 is similar to that of FIG. 1, except that the header 26 extends farther from the cylindrical body piece 20. In the head piece, an axial blind hole 28 is formed, the mouth of which is remote from the cylindrical body piece 20. This provides additional mechanical fixation of the tip 10. The securing of the tip 10 can be further enhanced by undercutting the hole 28, either to form a dovetail shape or with a radial groove, as shown in phantom in Fig. 2. In such an embodiment, the binder may not fall out of the recess when cured.

The specimen holder may alternatively be made of a refractory material, but otherwise similar to those described above.

In the embodiment, the binder 14 is a ceramic binder prepared by premixing 20% by weight of a sodium silicate solution and 80% by weight of zirconium silicate powder. The sodium silicate solution is an aqueous solution having a density of 1.37 g / cm 3 (1370 kgm <3>) prepared from a mixture of SiO 2 and Na 2 O in a weight ratio of 3.22: 1 becomes. At room temperature, the binder begins to set within minutes after mixing. In this example, the binder used is the High Temperature CC binder made by Omega Engineering, Inc.

To assemble the specimen binder is applied immediately after mixing on the mounting surface 24 and placed in the blind hole 28. A crystal is pressed through the binder 14 until it comes into contact with the underlying material of the specimen holder 12. The binder is allowed to cure for 48 hours at room temperature. In this state, a part of the crystal may protrude from the binder or the crystal may be completely enclosed in the binder.

The specimen can then be ground and polished so that the crystal and surrounding binder 14 is formed into a tip 10 having the desired shape and size.

Finally, the specimen is heated (in the present embodiment to 750 ° C) to achieve complete curing of the binder.

For ceramic binder with relatively large particles or lower adhesive forces, it is advantageous if the ceramic bond is supplemented by mechanical pinching, resulting in a test specimen as shown in Fig. 6.

This embodiment has a tip 30, a Prüfkörperhalter 32 and a binder mass 34.

The Prüfkörperhalter 32 has a cylindrical body piece, one end of which extends a head piece 36 in the form of a truncated cone. An axial bore 38 extends through the length of the Prüfstückhalters 32. A remote from the head piece 36 end portion 40 of the bore 38 is provided with an internal thread. The bore 38 in the head piece 36 tapers.

As an aid in the construction of the test specimen of Fig. 6, a pushing tool 50, as shown in Fig. 3, used. The pusher tool is substantially in the form of a bolt with a hex head 52 and a shaft 54 continuing from the head 52. The shaft 54 has a threaded portion near the head and a smaller diameter portion 56 away from the head. The portions of the shank 54 are selected so that the threaded portion can engage the thread cut in the bore 38 of the test piece holder 32, and that the unthreaded portion 56 fits snugly into the portion of the bore 32 that does not Thread is provided.

To assemble the test specimen, a crystal 60 is first inserted through the mouth 36 of the bore 38 of the specimen holder 32 remote from the head 36. The crystal 60 is chosen to have a size that allows a portion of it to protrude there from the bore where it emanates from the head 36, but so that it is too large to completely out of the head Bore 38 to be led out, and instead is clamped in the tapered portion of the bore 38. Then, a mass of freshly mixed binder 34 is inserted through the mouth 36 remote from the head 36 of the bore 32 in this.

The pusher tool 50 is then inserted into the bore 38, wherein the threads of the pusher tool 50 and the test piece holder 32 come into threaded engagement with each other. The pusher tool 50 is rotated by its head 52 to drive it into the bore 38 of the Prüfkörperhalters 32. The unthreaded portion of the shaft 54 of the pusher tool 50 acts as a piston in the cylinder formed by the unthreaded portion of the bore 38, so that the binder 34 is driven toward the headpiece 36. There, the binder 34 is forced to surround the crystal 60 and to fill the space surrounding the crystal 60 in the bore 38 as shown in FIG.

The binder 34 is then cured and the crystal 60 and header 36 are formed into a test specimen tip 30 as described above.

In these various embodiments, the crystal 60 is ground and polished by known methods to make it a test specimen tip. When the crystal is completely embedded in the binder or inserted into a holder supplementing the binder with a mechanical fuse, the polishing also includes a process that also shapes and polishes the binder or the material of the sample holder (or both) as needed, to form and expose the required specimen tip geometry. This can e.g. pyramidal, spherical or cylindrical.

In use, a test specimen embodying the invention may be heated by contact with a heated specimen or by heating the specimen assembly prior to testing using an attached heater.

The coefficients of thermal expansion of the components of the specimen (including specimen holder and binder) are as far as possible matched to exclude a different extent and potential consequential cracks in the binder.

The finished specimen can then be mounted in a trial fixture and used to perform experiments on specimens of material by a skilled person in a known manner. Such attempts may be made at elevated temperatures without the risk of the specimen deteriorating or damaging the specimen.

Claims (14)

1. test specimen for use in a material testing device, having a Prüfkörperhalter, which is designed for the purpose of attachment to the Werkstoffprüfvorrichtung, and which has a test piece tip carried by the test piece holder, the test piece tip being fastened to the test piece holder with a mass of hardened ceramic binder. 2. The test specimen according to claim 1, wherein the specimen tip is made of a piece of hard crystalline material, wherein the hard crystalline material is diamond or a crystalline ceramic. The test piece according to claim 1, wherein the test piece tip has been subjected to machining operations so as to have a predetermined shape and dimension. 4. Test specimen according to one of the preceding claims, wherein the binder comprises a cured mixture of sodium silicate or potassium silicate and zirconium silicate. 5. Test specimen according to one of the preceding claims, wherein the test specimen tip is mounted on a flat surface of the specimen holder or in a recess formed in the specimen holder. 6. Test specimen according to one of the preceding claims, wherein the test specimen tip is seated in a space in the specimen holder and is arranged so that it protrudes from the specimen holder. 7. test specimen according to claim 6, wherein the binder occupies a volume which surrounds the Prüfkörperspitze in the room. 8. A method of producing a test specimen according to any one of the preceding claims, wherein the binder in the uncured state will be applied to a specimen holder, wherein a crystal is pressed into the binder, and wherein the binder is cured. A method of producing a test piece according to any one of claims 1 to 7, wherein a crystal is introduced into a space in a test piece holder so as to partially protrude from the test piece holder, wherein uncured binder is introduced into the space at which causes is that the binder surrounds the crystal in the Prüfkörperhalter, and in which the binder is cured. The method of claim 8 or claim 9, wherein the test specimen tip is brought to the desired shape and dimensions by subjecting both the crystal and the binder to a process involving grinding and / or polishing. A method according to any one of claims 8 to 10, wherein the test piece is heated to a temperature close to a maximum operating temperature of the test piece to fully cure the binder. 12. Werkstoffprüfvorrichtung containing a test specimen according to one of the claims 1 to 7. 13. A material testing method in which a sample of material is mounted in a device according to claim 12, and wherein the test piece is made to make an impression, impact or abrasive contact with the sample. 14. Werkstoffprüfverfahren according to claim 13, wherein the test specimen and / or the sample is / is heated, in particular to a temperature of about 100 CC or to a temperature of about 500 ° C.