Structure and properties of low carbon steel after plasma-jet hard-facing of boron-containing coating

IF 0.4 Q4 METALLURGY & METALLURGICAL ENGINEERING Obrabotka Metallov-Metal Working and Material Science Pub Date : 2023-06-13 DOI:10.17212/1994-6309-2023-25.2-93-103
A. Balanovsky, V. V. Nguyen, N. Astafieva, R. Gusev
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Abstract

Introduction. One of the effective thermochemical methods for increasing the hardness of steel is boronizing by diffusion of boron atoms into the steel surface at high temperatures. As a result of boronizing, coatings are formed on the steel surface, consisting of columnar crystals of FeB and Fe2B. The volume fraction of phases and the thickness of the coatings depend on the heating temperature and the chemical composition of the base material and the saturating medium. The main disadvantage of these boronized layers is its high brittleness. Boronizing by plasma heating is one of the alternatives to the diffusion boronizing process to minimize the brittleness of the boronized layer. The purpose of the work: to form boride coatings on low-carbon steel using plasma-jet hard-facing. The research methods are: determination of the content of chemical elements using an electron probe micro-analyzer, metallographic studies, analysis of the phase composition of the boronized layer, as well as measurement of the microhardness of the coating after plasma-jet hard-facing. In this work boronized layers obtained on low-carbon steel 20 by plasma-jet hard-facing of a boron-containing coating are studied. Powdered amorphous boron was used as an alloying element. The parameter varied during plasma-jet hard-facing process is the current strength (120 A, 140 A and 160 A). Results and discussions. Based on the studies performed, it is found that it is possible to form boronized layers on the steel surface using plasma-jet hard-facing method. It is noted that the surface layer of the coating of the 1st and 2nd specimens after plasma-jet hard-facing has a heterogeneous structure, consisting of rows of different zones. The first zone has a hypereutectic structure, which consists of primary borides FeB and Fe2B, located in the eutectic, consisting of Fe2B and α-Fe. The second zone above the boundary with the base metal is represented by eutectic colonies composed of Fe2B and α-Fe. The third specimen is characterized by a hypoeutectic structure consisting of boride eutectic and primary dendrites of the α-solid solution of boron in iron. The maximum hardness is fixed on the surface of the first specimen and is 1,575 HV. The depth of the hardened layer increases with increasing current, but the hardness value and boron content decrease after treatment. The slight hardness gradient observed over the depth of the coating, as well as the gradual decrease in hardness due to the presence of the transition zone, are considered favorable for good adhesion of the boronized layer to the surface of the base material.
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低碳钢等离子喷镀含硼涂层后的组织与性能
介绍提高钢硬度的有效热化学方法之一是在高温下通过硼原子扩散到钢表面进行硼化。作为硼化的结果,在钢表面形成由FeB和Fe2B的柱状晶体组成的涂层。相的体积分数和涂层的厚度取决于加热温度以及基材和饱和介质的化学组成。这些硼化层的主要缺点是其高脆性。等离子体加热硼化是扩散硼化工艺的替代方案之一,以最大限度地降低硼化层的脆性。本工作的目的是:利用等离子体喷射硬面在低碳钢表面形成硼化物涂层。研究方法有:用电子探针显微分析仪测定化学元素含量,金相研究,分析渗硼层的相组成,以及测量等离子体喷射硬面后涂层的显微硬度。在本工作中,研究了通过含硼涂层的等离子体喷射硬面在低碳钢20上获得的硼化层。粉末状无定形硼被用作合金元素。等离子体喷射硬面工艺过程中变化的参数是电流强度(120A、140A和160A)。结果和讨论。基于所进行的研究,发现使用等离子体喷射硬面方法在钢表面形成硼化层是可能的。值得注意的是,第一和第二样品的涂层在等离子体喷射硬面处理后的表面层具有非均匀结构,由不同区域的行组成。第一个区具有过共晶结构,由初生硼化物FeB和Fe2B组成,位于由Fe2B和α-Fe组成的共晶中。与基底金属边界上方的第二个区域由Fe2B和α-Fe组成的共晶集落表示。第三个试样的特征是由硼在铁中的α-固溶体的硼化物共晶和初生枝晶组成的亚共晶结构。最大硬度固定在第一个试样的表面上,为1575HV。硬化层的深度随着电流的增加而增加,但处理后硬度值和硼含量降低。在涂层深度上观察到的轻微硬度梯度,以及由于过渡区的存在而导致的硬度的逐渐降低,被认为有利于硼化层与基材表面的良好粘附。
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来源期刊
Obrabotka Metallov-Metal Working and Material Science
Obrabotka Metallov-Metal Working and Material Science METALLURGY & METALLURGICAL ENGINEERING-
CiteScore
1.10
自引率
50.00%
发文量
26
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