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1

Bimetal Castings with a Titanium Working Layer

Dulska Agnieszka

Archives of Foundry Engineering

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2023

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Vol. 23, iss. 2

21--28

EN

The paper presents the technology of bimetallic castings using the casting method of applying layers directly during the casting process. The bimetallic casting consists of a load-bearing part (typical casting material, i.e. gray cast iron with flake graphite) and a working part (titanium insert). The titanium insert was made by printing using the selective laser melting (SLM) method, and its shape was spatial. The verification of the bimetallic castings was carried out mainly based on metallographic tests, temperature and thickness measurements. Structure examinations containing metallographic microscopic studies with the use of a light microscope (LOM) and a scanning electron microscope (SEM) with microanalysis of the chemical composition (energy dispersive spectroscopy - EDS).The aim of the tests was to select the appropriate geometrical insert parameters for bimetallic castings within the tested range. The correct parameters of both the insert, pouring temperature and the casting modulus affect the diffusion processes and, consequently, the formation of carbides and the creation of bimetallic castings.

2

Self-hardening of X46Cr13 Steel Integrated with Base from Grey Cast Iron in Bimetallic System

Przyszlak N., Wróbel T.

Archives of Foundry Engineering

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2019

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iss. 2

29--34

EN

The paper presents the technology of manufacturing layered castings, consisting of grey cast iron (base part) and high-chromium stainless steel (working part/layer). The aim of researches was an attempt of integration of heat treatment of steel X46Cr13 grade with founding of grey cast iron in bimetallic system and determination of the influence of cooling rate of bimetallic system in classical sand mould with bentonite on microstructure and hardness of the working layer. The castings were manufactured using mould cavity preparation method, where steel plate was poured by grey cast iron using different pouring temperature and thickness of base part. Then, the quality of joint between cast iron and steel plate was estimated by using ultrasonic non-destructive testing. The efficiency of heat treatment process was analysed by measurement of hardness and in metallographic examination. Conducted studies showed, that self-hardening’s ability of steel X46Cr13 let obtain technologically usable layered casting characterized by hardness of working surface up to 35 HRC.

3

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.

4

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.

5

The influence of the selected technological factors on the quality of bimetallic castings alloy steel-silumin

Szymczak T.

Archives of Foundry Engineering

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2011

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Vol. 11, iss. 3 spec.

215--226

EN

The work presents the research results of the influence of the selected technological factors on the improvement of bimetallic castings alloy steel-silumin. The following alloy steel grades were used for the research: X6CrNiTi18-10, X39Cr13 and HS6-5-2. The sets of the mentioned steel grades were alphinated in silumin AlSi5 and were poured with this silumin or complex silumin AlSi5Ni5Cu4MgCrMoWV into the casting mold obtaining bimetallic castings as a result. Moreover, the following technological factors of the process of bimetallic casting production were analyzed: the time from removing of the set from the alphinizing bath till pouring it with the silumin into the casting mold “τp”, the temperature of the initial heating of the casting mold “t2,0” and the temperature of the silumin for pouring of the casting mold “tz”. It follows from the presented results that the best connecting quality of the analyzed castings is obtained when using: the possible short time “τp” and low temperature values “t2,0” and “tz”.

6

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.