In metallography, mounting is typically the second process step after sectioning. Mounting encapsulates the sampled material with a plastic shell and prepares the sample for the following metallographic grinding and polishing step. In many cases it leads to a simplified sample preparation and thus to better results.
QATM is a leading manufacturer and supplier of high-quality consumables as well as a range of innovative machines, from hot mounting presses to UV mounting devices. The QATM application experts combine decades of experience with thousands of processed materialographic samples and will be happy to assist with your application.
In metallography, a distinction is made between hot and cold mounting, depending on whether heat is required for the polymerization process. It must be noted that during cold mounting polymerization temperatures of up to 130 °C may arise when using, e. g., methyl acrylates.
Today, the term cold mounting is generally used for all methods where no or small pressures (<5 bar) are applied.
When it comes to the selection of metallographic mounting methods, arguments for or against a certain method can be found. The below overview presents the process differences between metallographic hot and cold mounting.
Feature | 金相热镶嵌 | Metallographic Cold Mounting |
---|---|---|
Devices | Mounting press | Take-off the pressure device if necessary, infiltration set |
Plastic types | Phenolic resin, Acrylic resin, Epoxy resin | Methyl methacrylate, Polyester resin, Epoxy resin |
Time expenditure per process | 10 - 15 min | 5 minutes – 12 h (depending on the plastic types) |
Handling | Simple, granulate/powder is filled in the mold assembly | Observe dosage (volume or weight %), mixing of 2-3 components |
Flexibility in terms of shape selection | Limited, significant additional costs | Large, with low cost |
Result | Plane-parallel specimens, depending on the type of granules, hardness, low gap and transparency can be achieved | No plane-parallel specimens, depending on the plastic selection, hardness, low gap and transparency can be achieved |
Cost expenditure for plastic/granulate | Costs are considerably lower | Costs are considerably higher |
Occupational safety | Observe safety data sheets. Use extraction unit | Observe safety data sheets. Use take-off unit |
Metallographic hot and cold mounting are not in direct competition, but there is a certain overlap in application ranges. The most important criteria for compounds are hardness, abrasion resistance, shrinkage, and chemical resistance.
Low shrinkage during solidification and good adhesion to the specimen are important. Without these, a gap will form between the specimen and the mounting material. This causes edge rounding, accumulation, and carryover of grinding and polishing media or the rupture of surface coatings.
The following points need to be observed as well:
金相热镶嵌树脂 | Metallographic cold mounting compounds |
---|---|
Powder, granules or preforms are compacted under pressure and heat in a press | Liquid and/or powder is mixed with hardener and poured into mounting moulds |
Raw material can be stored for as long as required | Raw material must be stored in a cool place and has a limited shelf life |
Processing time for one sample is 10 to 18 minutes, a maximum of two samples per cylinder is possible | Curing time for one sample is approx. 15 minutes to 12 hours. Several samples can be mounted simultaneously |
Duroplast: Phenolic resin (bakelit), epoxy resin | Duroplast: Epoxy resin, polyester resin |
Polymerised to a mass that cannot be softened further | Polymerised to a mass that cannot be softened further |
Heating up to approximately 150-200 °C under pressure (200 bar) | Pay attention to temperature of polymerization during polymerization. This depends on the mixing ratio, the external temperatures, the quantity of components used and the heat dissipation of the mounting moulds |
Thermoplastics: Acrylates | Thermoplastics: Acrylates |
Can be softened again, heating without pressure, cooling under pressure | Can be softened again, temperature increase 50-120 °C, short hardening time |
Hot mounting could also be called hot biaxial pressing. It is a process in which a granulated polymeric material is softened, compressed, and cooled down sequentially. The process is carried out in a metallographic hot mounting press, designed for this application.
Of course, this method may only be applied on sufficiently pressure- and temperature-resistant samples with simple geometries. The process is carried out at temperatures of 150 to 200°C, while the pressure depends on the mould diameter and ranges from 100 to 300 bar. After placing the sample on the lower ram, the mounting material is added and the process started.
Two types of materials are used:
Property | Duroplast | Thermoplastic | ||
Phenolic resin | Epoxy resin | |||
Filling material | Medium | Copper, graphite | Glass, mineral material | None |
Hardness | Medium | Medium | Very high | Low |
Gap formation | Existent | Existent | Very low in gaps | Existent |
Grindability | Good | Good | Very good (not for grinding stones) | Satisfactory |
Chemical resistance | Good | Good | Good | Satisfactory |
Electrical conductivity | None | Good to very good | None | None |
Product | Bakelit black, red, green | Duroplast black | EPO black, EPO max | Thermoplastic |
Thermosets are usually cured between 150°C and 180°C, while the processing window of thermoplastics is slightly bigger. Because they are hardened during the cooling process, their cooling times, depending on the mould diameter, are longer than those of thermosets. In this case, the cooling rate, which is usually lower, must be considered.
Therefore, metallographic hot mounting presses have pulsed cooling modes, which contribute to the release of the plastics’ internal stresses during curing. This prevents crack formation and guarantees a clear sample.
Parameters | Duroplast | Thermoplastic |
---|---|---|
Polymerization range | 150-190°C | 130-195°C |
Holding time | 5-8 min* | 5-8 min* |
Cooling time | 3-6 min* | 7-10 min* |
Pressure | 150-180 bar* | 160-190 bar* |
* Depending on the diameter of the mould assembly; the greater the mold diameter, the more pressure and time is needed. |
Due to the required process parameters, hot mounting of metallographic samples is a limited application. These limitations apply to electronic assemblies (solders/composites) or pressure-sensitive materials, such as wires or sheets with small cross-sections. In modern presses, this fact is taken into account by shifting the pressure onset to the point where the target temperature is reached. This extends the application range of the process, but complex network structures or porous rock cannot be hot mounted.
The plane-parallelism of the samples and the easy handling of the process are of advantage, especially in hardness testing.
It is possible to use several compounds in layers. This allows the specimen to be mounted in hard a medium. Afterwards, a cheaper filling material is used, which is covered by a transparent material to enclose a sample identification.
Four samples mounted using different compounds
The technical requirements of cold mounting are minimal compared to the metallographic hot mounting process. Only a mold and the cold material compound are required. In addition to hardness and abrasion resistance, shrinkage, curing (pot life), and exothermic heat development are the main selection criteria. The process is carried out as follows:
The sample is placed in a mould and the exact weight or volume proportions of the mounting components are carefully measured. These are then thoroughly mixed (left image) and poured into the mould (right image). Small samples should be fixed in place before the casting process.
Four classes of materials are available:
The moulds used for metallographic cold mounting are reusable. Here only the most commonly used moulds are described. Various constructions, for example based on polymer-coated metal parts or different plastics, may be observed in laboratory practice.
真空浸渍
Porous materials such as ceramics, sintered materials or spray coatings must be mounted under vacuum. Only then can all open pores connected to the surface be filled with the mounting material. This is possible with epoxy resins since vapor pressure and viscosity are sufficiently low. Nevertheless, the vacuum must be limited to pressures below 0.8 bar, otherwise the low-boiling components of the epoxy system will release gas or start to boil.
This process can be used to reinforce and protect sensitive materials. Unwanted preparation effects such as breakouts, cracks and excessiveporosity are reduced to a minimum. However, this only applies to mainly open-pored materials; others, like rather densely sintered ceramics, cannot be properly infiltrated. Damage due to reaction heat or pressure is not to be expected – another reason why there is no alternative to this procedure for porous materials.
Application of overpressure
Metallographic cold mounting under pressure only makes sense when using acrylates. A simple pressure device is required (compressed air connection 5-6 bar). Better transparency is achieved with unfilled methacrylates. The applied overpressure of 2 to 2.5 bar increases the boiling point of the compound and suppresses the formation of gas bubbles during polymerization. This enables crystal-clear mounted samples. Pressure cannot replace vacuum as the gas volume cannot completely escape from the pore volume. Therefore, open pores remain partially unfilled and cause the formation of preparation artefacts.
Even when high-quality products are used, the formation of marginal gaps cannot always be avoided and occurs especially during cold mounting. This is often due to inadequate preparation of the sample or its geometry. To avoid the formation of marginal gaps, attention should be given to the following:
simple
difficult
For a sharp-edged preparation and protected boundary areas, it is crucial to observe the correct hardness of the metallographic mounting material. In general, a mounting material should be as hard and impact-resistant as possible to achieve a metal-like removal behavior. For this reason, high-filled systems are always used when transparency is not required. This reduces the shrinkage of the material.
The gaps between sample and metallographic mounting material should be as small as possible. Marginal gaps and edge rounding bear the risk of carrying over dirt and grinding or polishing particles. This leads to a deterioration of the metallographic preparation result. Leaking etchant or cleaning alcohol can then falsify the micrographs due to after-etching or discoloration in areas close to the gaps.
Shrinkage gap - poor transition of mounting material to sample
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