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1

Designing of X46Cr13 Steel Heat Treatment in Condition of Casting Mould

Przyszlak Natalia, Piwowarski Grzegorz

Archives of Foundry Engineering

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2023

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Vol. 23, iss. 2

119--126

EN

The paper presents issues related to the technology of layered castings manufactured in the system: working part made of high-chromium steel X46Cr13 - base part made of gray cast iron with flake graphite, using the mould cavity preparation technology. Considering the high hardenability of the above-mentioned steel grade, the aim of the research was to optimize the casting parameters of gray cast iron in such a way that it would be possible to perform heat treatment of X46Cr13 steel directly in the casting mould. As part of the research, the geometry of the working and base parts of layered castings was selected, and guidelines for mould technology from the point of view of the moulding sand were developed. In order to control the cooling rate, three matrix of the moulding sand were used - quartz sand, chromite sand and silicon carbide, with the same granularity. The thermal conductivity coefficient of sands made on selected matrix, bound with synthetic resin in the ratio of 30:1, was experimentally determined. Then, the bimetal casting process in a given mass was simulated in the MagmaSoft® (ver. 5.4.1). The purpose of the simulation was to determine the maximum virtual temperature Tm in the thermal center of the outer surface of the X46Cr13 steel insert. From the point of view of the research purpose, the insert was expected to heat up to the austenitization temperature, i.e. at least 950°C.

2

The Impact of Selected Geometry Parameter of Titanium Spatial Insert on the Surface Layer Formation on Grey Cast Iron

Dziwoki G., Dulska A., Szajnar J., Król M.

Archives of Foundry Engineering

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2019

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iss. 1

58--62

EN

The paper presents a method of producing a grey cast iron casting locally reinforced with a titanium insert printed using SLM method (Selective Laser Melting). This article attempts to examine the impact of the selected geometry of titanium spatial insert on the surface layer formation on grey cast iron. The scope of the research focuses on metallographic examination - observation and analysis of the structure of the reinforced surface layer on a light and scanning microscope and a hardness measurement of the titanium layer area. Based on the obtained results, it was concluded that the reaction between titanium insert and metal (grey cast iron) locally develops numerous carbides precipitation (mainly TiC particles), which increases the hardness of the reinforced surface layer and local strengthening of the material. The ratio between the thickness of the support part (grey cast iron) and the working part (titanium insert) affects the resulting layers connection structure. The properties of the obtained reinforced surface layer depend mainly on the geometry of the insert (primarily on the internal dimensions of the connector) and the volume of the casting affecting the re-melting of the insert. A more concentrated structure of carbides precipitation occurs in castings with a full connector insert.

3

The quality of the joint between alloy steel and unalloyed cast steel in bimetallic layered castings

Wróbel T.

Archives of Foundry Engineering

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2012

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Vol. 12, iss. 1

119-124

EN

In paper is presented technology of bimetallic layered castings based on founding method of layer coating directly in cast process so-called method of mould cavity preparation. Prepared castings consist two fundamental parts i.e. bearing part and working part (layer). The bearing part of bimetallic layered casting is typical foundry material i.e. ferritic-pearlitic unalloyed cast steel, whereas working part (layer) is plate of austenitic alloy steel sort X2CrNi 18-9. The ratio of thickness between bearing and working part is 8:1. The aim of paper was assessed the quality of the joint between bearing and working part in dependence of pouring temperature and carbon concentration in cast steel. The quality of the joint in bimetallic layered castings was evaluated on the basis of ultrasonic non-destructive testing, structure and microhardness researches.

4

The influence of selected cast parameters on quality of joint in layered castings

Wróbel T., Cholewa M.

Archives of Foundry Engineering

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2012

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Vol. 12, iss. 2

105-110

EN

In paper is presented technology of bimetallic layered castings based on founding method of layer coating directly in cast process so-called method of mould cavity preparation. Prepared castings consist two fundamental parts i.e. bearing part and working part (layer). The bearing part of bimetallic layered casting is typical foundry material i.e. unalloyed cast steel, whereas working part is plate of austenitic alloy steel sort X2CrNi 18-9. The ratio of thickness between bearing and working part is 8:1. The aim of paper was assessed the quality of the joint between bearing and working part in dependence of pouring temperature and carbon concentration in cast steel. The quality of the joint in bimetallic layered castings was evaluated on the basis of ultrasonic non-destructive testing, structure and microhardness researches.

5

Odlewy bimetalowe z wysokochromową warstwą roboczą

Wróbel T., Szajnar J., Cholewa M., Wróbel P., Tenerowicz S.

Archives of Foundry Engineering

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2012

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Vol. 12, iss. 2s

87--90

PL

W prac przedstawiono technologię bimetalicznych odlewów warstwowych opartą na odlewniczej metodzie nakładania warstw bezpośrednio w procesie odlewania tzw. metodę preparowania wnęki formy. Wykonane tą metodą bimetaliczne odlewy warstwowe złożone są z dwóch zasadniczych elementów tj. części nośnej oraz części (warstwy) roboczej. Część nośną odlewu warstwowego stanowiło typowe tworzywo odlewnicze tj. żeliwo szare z grafitem płatkowym, natomiast część roboczą stanowiła stal stopowa ferrytyczna gatunku X6Cr 13 lub martenzytyczna gatunku X39Cr 13. Weryfikację wykonanych bimetalicznych odlewów warstwowych przeprowadzono w oparciu o nieniszczące badania ultradźwiękowe, badania metalograficzne makro- i mikroskopowe.

EN

In paper is presented technology of bimetallic layered castings based on founding method of layer coating directly in cast process so-called method of mould cavity preparation. Prepared castings consist two fundamental parts i.e. bearing part and working part (layer). The bearing part of bimetallic layered casting is typical foundry material i.e. grey cast iron with flake graphite, whereas working part is plate of ferritic alloy steel sort X6Cr 13 or martensitic alloy steel sort X39Cr 13. The quality of the joint in bimetallic layered castings was evaluated on the basis of ultrasonic non-destructive testing, metallographic macro and microscopic researches.

6

Odlewy bimetalowe z chromowo-nikolową[!] warstwą roboczą

Wróbel T., Szajnar M., Cholewa M., Wróbel P., Suchoń J., Tenerowicz S.

Archives of Foundry Engineering

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2012

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Vol. 12, iss. 2s

81--86

PL

W prac przedstawiono technologię bimetalicznych odlewów warstwowych opartą na odlewniczej metodzie nakładania warstw bezpośrednio w procesie odlewania tzw. metodę preparowania wnęki formy. Wykonane tą metodą bimetaliczne odlewy warstwowe złożone są z dwóch zasadniczych elementów tj. części nośnej oraz części (warstwy) roboczej. Część nośną bimetalicznego odlewu warstwowego stanowiło typowe tworzywo odlewnicze tj. staliwo niestopowe lub żeliwo szare z grafitem płatkowym, natomiast część roboczą stanowiła stal stopowa austenityczna gatunku X2CrNi 18-9 lub ferrytyczno-austenityczna gatunku X2CrNiMoN 22-5-3. Weryfikację wykonanych bimetalicznych odlewów warstwowych przeprowadzono w oparciu o nieniszczące badania ultradźwiękowe, badania struktury oraz mikrotwardości. Ponadto wykonano symulację komputerową procesu krzepnięcia bimetalicznych odlewów warstwowych w programie NovaFlow&Solid.

EN

In paper is presented technology of bimetallic layered castings based on founding method of layer coating directly in cast process so-called method of mould cavity preparation. Prepared castings consist two fundamental parts i.e. bearing part and working part (layer). The bearing part of bimetallic layered casting is typical foundry material i.e. unalloyed cast steel or grey cast iron with flake graphite, whereas working part is plate of austenitic alloy steel sort X2CrNi 18-9 or ferritic-austenitic alloy steel sort X2CrNiMoN 22-5-3. The quality of the joint in bimetallic layered castings was evaluated on the basis of ultrasonic non-destructive testing, structure and microhardness researches. Moreover was made computer simulation of solidification of bimetallic layered casting with use of NovaFlow&Solid software.

7

Zastosowanie ochładzalnika w celu rozdrobnienia struktury w odlewie bimetalicznym

Suchoń J.

Archiwum Odlewnictwa

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2003

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R. 3, nr 10

214--220

PL

Prezentowana praca stanowi próbę podniesienia twardości a pośrednio również odporności na ścieranie odlewów bimetalicznych poprzez zastosowanie ochładzalnika.

EN

Presented work shows the first test to increasing of hardness and also connected with it abrasion resistance of bimetallic castings through the chill application.

8

Wybrane badania walców redukcyjnych wykonanych jako odlewy warstwowe

Olszyński J., Uhl W., Stefański K.

Krzepnięcie Metali i Stopów

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2000

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R. 2, nr 43

393--398

PL

Walce stosowane w walcarkach redukcyjnych wykonywane są w kraju z zastosowaniem prostych technologii odlewniczych, czego efektem jest niski uzysk, wysoki koszt obróbki mechanicznej i w efekcie wysoki koszt końcowego produktu, którym jest walec hutniczy. W czeskich odlewniach, z których niektóre polskie walcownie sprowadzają walce, stosują technologię odśrodkową odlewania walców, dodatkowo walce wykonuje się jako odlewy warstwowe. Prowadzi to do znacznego obniżenia kosztów ich realizacji przy porównywalnej w stosunku do walców krajowych jakości.