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GEOPOL®. The Innovated Environment Friendly Inorganic Binder System

M. Vykoukal A. Burian M. Přerovská
Archives of Foundry Engineering | 2019 | vol. 19 | No 1 | 109-116 | DOI: 10.24425/afe.2019.127103
Keywords Geopolymer binder GEOPOL® Inorganic binder Mould and core environment
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Abstract

This paper deals with the complete technology of inorganic geopolymer binder system GEOPOL® which is a result of long term research and development. The objective of this paper is to provide a theoretical and practical overview of the GEOPOL® binder system and introduce possible ways of moulds and cores production in foundries. GEOPOL® is a unique inorganic binder system, which is needed and welcomed in terms of the environment, the work environment, and the sustainable resources. The GEOPOL® technology is currently used in the foundries for three basic production processes/technologies: (1) for self-hardening moulding mixtures, (2) sand mixtures hardened by gaseous carbon dioxide and (3) the hot box technology with hot air hardening. The GEOPOL® technology not only solves the binder system and the ways of hardening, but also deals with the entire foundry production process. Low emissions produced during mixing of sand, moulding, handling, and pouring bring a relatively significant improvement of work conditions in foundries (no VOCs). A high percentage of the reclaim sand can be used again for the preparation of the moulding mixture.

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Authors and Affiliations

M. Vykoukal
A. Burian
M. Přerovská

Research on Assessment of the Applicability of Malted Barley Binder in Moulding Sand Technology

B. Samociuk B. Gal D. Nowak
Archives of Foundry Engineering | 2021 | vo. 21 | No 1 | 74-80 | DOI: 10.24425/afe.2021.136081
Keywords Innovative foundry technologies and materials Mechanical properties Moulding and core sand Organic binder Malted barley
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Abstract

The foundry industry is looking for solutions that improve the quality of the finished product and solutions that reduce the negative impact of the industry on the natural environment [26]. This process leads to work on the use of new or previously unused materials for binders. Organic and inorganic foundry binders are replaced by renewable materials of plant origin to meet the requirements of both the foundry customers and the environmental and health and safety regulations. The aim of this work was to identify the applicability of renewable and organic malted barley binder in moulding sand technology. The influence of the malt binder content on dry tensile strength, dry bending strength, dry permeability, dry wear resistance and flowability were evaluated. The results show that the malted barley binder can be self-contained material binding the high-silica sand grains. Selected mechanical properties of moulding sands were found to increase with an increase in binder content. It was observed that malted barley binder creates smooth bonding bridges between high-silica sand grains.
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Bibliography

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Authors and Affiliations

B. Samociuk
1
ORCID: ORCID
B. Gal
1
D. Nowak
1
ORCID: ORCID
  1. Department of Foundry Engineering, Plastics and Automation, Wroclaw University of Technology, ul. Smoluchowskiego 25, 50-372 Wrocław, Poland

Analysis of Influence of Sand Matrix on Properties of Moulding Compounds Made with Furan Resin Intended for 3D Printing

D.R. Gruszka R. Dańko M. Dereń A. Wodzisz
Archives of Foundry Engineering | 2024 | Accepted articles | DOI: 10.24425/afe.2024.149267
Keywords Furfuryl resin Foundry engineering Sand moulds and cores 3D printing Binder jetting
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Abstract

Binder jetting (BJ) sand printing is a 3D printing process in which a sand mould or sand core is produced from an STL file. A single layer of a sand matrix consisting of one or more grains in height of sand is applied to a worktable, and then a liquid resin or binder is applied to bond the grains together. This process is repeated until the final result matches the CAD model. The sand matrix is the main component of ceramic cores and moulds. The present study aims to demonstrate the influence of the matrix used on the properties of the resulting moulding sand. Three types of sand matrices were selected for the study. The first was a quartz matrix for 3D printing with binder jetting; this is characterised by a sharp geometry that allows for proper layering during printing. Ordinary quartz sand was also used for the study; this type of sand is usually used for the production of sand cores in the hotbox process, among other things. The shape of this sand is irregular. The last matrix to be tested was Cerabeads sand; this was selected because its spherical geometry clearly distinguishes it from the other two matrices. The matrices were analysed for their grain sizes. Scanning electron microscope images were also taken to compare the geometries and chemical compositions of the respective matrices. In presented research utilises a sand matrix for the production of self-curing compounds with furan resin dedicated for binder jetting 3D printing. The moulding masses were produced in a laboratory circulation mixer. The laboratory moulds were produced with wooden core boxes and pre-compacted by vibration. The samples from the matrix for the 3D printing were produced using the binder jetting method. The samples were produced to determine the flexural strength, tensile strength, gas permeability, hot distortion, and apparent density. It was not possible to carry out tests for the Cerabeads sand, as the obtained moulds were too brittle to perform adequate tests. Tests with the other matrices have shown that the shape and size of the matrix affect the apparent density and gas permeability.
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Bibliography

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Authors and Affiliations

D.R. Gruszka
1
ORCID: ORCID
R. Dańko
1
ORCID: ORCID
M. Dereń
1
A. Wodzisz
1
  1. AGH University of Krakow, Faculty of Foundry Engineering, Poland

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