Effects of Cooling Rate during Quenching and Tempering Conditions on Microstructures and Mechanical Properties of Carbon Steel Flange.

Sunmi Shin,Byung-Jun Kim,Haeju Jo,Jong Bae Jeon,Yong-Sik Ahn,Chang Yong Choi,Moonseok Kang,Wookjin Lee,Geon-Woo Park,Hee Sang Park

doi:10.3390/ma13184186

Sunmi Shin, Byung-Jun Kim + Show 8 more

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https://doi.org/10.3390/ma13184186

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Abstract

This study investigated the mechanical properties of steel in flanges, with the goal of obtaining high strength and high toughness. Quenching was applied alone or in combination with tempering at one of nine combinations of three temperatures TTEM and durations tTEM. Cooling rates at various flange locations during quenching were first estimated using finite element method simulation, and the three locations were selected for mechanical testing in terms of cooling rate. Microstructures of specimens were observed at each condition. Tensile test and hardness test were performed at room temperature, and a Charpy impact test was performed at −46 °C. All specimens had a multiphase microstructure composed of matrix and secondary phases, which decomposed under the various tempering conditions. Decrease in cooling rate (CR) during quenching caused reduction in hardness and strength but did not affect low-temperature toughness significantly. After tempering, hardness and strength were reduced and low-temperature toughness was increased. Microstructures and mechanical properties under the various tempering conditions and CRs during quenching were discussed. This work was based on the properties directly obtained from flanges under industrial processes and is thus expected to be useful for practical applications.

Highlights

The flange is a component used to interconnect pipelines and must provide a strong and reliable connection
According to the morphological characteristics, the matrix is classified as granular bainitic ferrite (GBF), lath bainitic ferrite (LBF), acicular ferrite (AF) and quasi-polygonal ferrite (QPF), and the secondary phases are classified as martensite (M), martensite–austenite constituent (MA), degenerated pearlite/pearlite (DP/P) and carbide (C)
In fast CR (FC)-Q (Figure 4a,b), the matrix was mainly composed of GBF (47 ± 4.1% area fraction), followed by AF (16 ± 4.0%) and LBF (13 ± 1.0%), and the secondary phase was mostly M (17 ± 2.0%) with small amounts of DP/P (5 ± 1.5%) and MA (2 ± 0.2%)

Summary

Introduction

The flange is a component used to interconnect pipelines and must provide a strong and reliable connection. Since pipelines are increasingly being developed for harsh environments such as high pressure, low temperature and corrosive atmospheres, flanges are required to have excellent mechanical properties and reliability [1,2,3,4,5]. Low-carbon steel sheets have various microstructures and various characteristics. According to the morphological characteristics, the matrix is classified as granular bainitic ferrite (GBF), lath bainitic ferrite (LBF), acicular ferrite (AF) and quasi-polygonal ferrite (QPF), and the secondary phases are classified as martensite (M), martensite–austenite constituent (MA), degenerated pearlite/pearlite (DP/P) and carbide (C). LBF has a parallel lath shape and has relatively higher strength than GBF due to the fine laths and rich carbon content [25,26,27]

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