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Attempts to Prepare Precision Composite Castings by Sintering Al2O3/AlSi11 Using Underpressure

P. Szymański K. Gawdzińska D. Nagolska
Archives of Foundry Engineering | 2020 | vol. 20 | No 1 | 49-54 | DOI: 10.24425/afe.2020.131282
Keywords Innovative foundry technologies and materials rapid prototyping Composites
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Abstract

This article presents the preparation of composite casts made using the technology of precise casting by the method of melted models. The composite was reinforced with the ceramic sinter from Al2O3 particle shaped in a printed polystyrene female mould, which was fired together with precured ceramics. The resulting ceramic preform, after being saturated with paraffin and after the filling system is installed, was filled with liquid moulding sand and fired together with the mould. The reinforcement was saturated by means of the counter-pressure exerting action on the metal column, being a resultant of pressures inside and outside the chamber. The preliminary assessment showed no apparent defects in the shape of the cast. The casting was measured and the figures were compared with the dimensions of the matrix in which the reinforcing preform was made, the preform after firing and after saturation with paraffin. The results were presented in a table and dimensional deviations were determined. The composite casting was subjected to metallographic tests, which excluded any porous defects or damage to the reinforcement. It can therefore be said that, according to the predictions resulting from the previous calculations, the pressure values used allowed for complete filling of the reinforcement capillaries. The proposed method is therefore suitable for the preparation of precision composite castings with complex shapes.

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Authors and Affiliations

P. Szymański
K. Gawdzińska
D. Nagolska

Determination of Duration and Sequence of Vacuum Pressure Saturation in Infiltrated MMC Castings

K. Gawdzińska D. Nagolska P. Szymański
Archives of Foundry Engineering | 2018 | vol.18 | No 1
Keywords MMC saturation Determination of process parameters Time of infiltration Gypsum mold
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Abstract

The paper presents a detailed description of one of the newest methods of vacuum saturation of reinforcing preforms in gypsum molds. As an appropriate selection of the infiltration time is a crucial problem during realization of this process, aim of the analysis shown in the paper is to present methods of selection of subatmospheric pressure application time, a sequence of lowering and increasing pressure, as well as examining influence of structure of reinforcing preforms on efficiency of this process. To realize the aim, studies on infiltration of reinforcing preforms made of a corundum sinter of various granulation of sintered particles with a model alloy were conducted. The infiltration process analysis was carried out in two stages. The first stage consisted in investigation of influence of lengthening of sucking off air from the reinforcing preforms on efficiency of this process. In the second stage, an analysis of influence of a two-staged infiltration process on saturation of the studied materials was conducted. Because the studied preforms were of similar porosity, the obtained differences of the saturation level of particular preforms have shown, that the saturation process is influenced mostly by size of pores present in the reinforcement. Because of these differences, each reinforcement type requires individual selection of time and sequence of the saturation process. For reinforcements of higher pore diameter, it is sufficient to simply increase air sucking off time to improve the saturation, while for reinforcement of smaller pore diameter, it is a better solution to apply the two-staged process of sucking off air. Application of the proposed analysis method allows not only obtaining composite castings of higher quality, but also economical optimization of the whole process.

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Authors and Affiliations

K. Gawdzińska
D. Nagolska
P. Szymański

Manufacturing of Composite Castings by the Method of Fused Models Reinforced with Carbon Fibers Based on the Aluminum Matrix

P. Szymański
Archives of Foundry Engineering | 2023 | vol. 23 | No 3 | 118-123 | DOI: 10.24425/afe.2023.146670
Keywords Castings Metal matrix composite (MMC) AlSi matrix Casting by melted models
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Abstract

The paper presents an attempt to produce aluminum matrix composites reinforced with short carbon fibers by precision casting in a chamber with a pressure lower than atmospheric pressure. The composite casting process was preceded by tests related to the preparation of the reinforcement. This is related to the specificity of the precision casting process, in which the mold for shaping the castings is fired at a temperature of 720°C before pouring. Before the mold burns, the reinforcement must be inside, while the carbon fiber decomposes in the atmosphere at 396°C. In the experiment, the reinforcement in the form was secured with flake graphite and quartz sand. The performed firing procedure turned out to be effective. The obtained composite castings were evaluated in terms of the degree of alloy saturation and the displacement of carbon fibers. As a result of the conducted tests, it was found that as a result of unfavorable arrangement of fibers in the CF preform, the flow of metal may be blocked and porosity may appear in the casting.
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Bibliography

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Authors and Affiliations

P. Szymański
1
ORCID: ORCID
  1. Institute of Materials Technology, Poznan University of Technology, Piotrowo 3, 61-138 Poznań, Poland

Evaluation of the Cause and Consequences of Defects in Cast Metal-Ceramic Composite Foams

P. Popielarski R. Sika D. Czarnecka-Komorowska P. Szymański M. Rogalewicz K. Gawdzińska
Archives of Foundry Engineering | 2021 | vo. 21 | No 1 | 81-88 | DOI: 10.24425/afe.2021.136082
Keywords Foams Composites Casting Defects Failure mode and effects analysis
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Abstract

In this research, the quality of manufactured cast metal-ceramic foams (manufactured using blowing gas) was tested. The causes responsible for defect formation in the composite foams and their consequences were analyzed using the FMEA (Failure Mode and Effects Analysis) method, which is a useful tool for minimizing losses caused by low product quality. This method involves analytically determining correlations between the cause and consequences of potential product defects, and it takes into account the criticality factor (risk). The FMEA analysis showed that pore breaks were the most "critical defect" (with the highest number of effects on the product, the Risk Priority Number, affecting the quality of the composite foam). The second most critical defect was discontinuities in the foam frame structure. Destruction or damage to the foam structure (although very rare) deprived the composite foam of its primary function, which is to reinforce the product. The third most critical defect was non-uniform foam pore size.
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Authors and Affiliations

P. Popielarski
1
ORCID: ORCID
R. Sika
1
D. Czarnecka-Komorowska
1
ORCID: ORCID
P. Szymański
1
ORCID: ORCID
M. Rogalewicz
1
K. Gawdzińska
2
ORCID: ORCID
  1. Institute of Materials Technology, Poznan University of Technology Piotrowo 3, 61-138 Poznań, Poland
  2. Faculty of Marine Engineering, Maritime University of Szczecin, Willowa 2-4, 71-650 Szczecin, Poland

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