The surfacing technologies are used for constitution of protection layer against wear and is destined for obtaining coating with high
hardness. Among many weldings methods currently used to obtain the hard surface layer one of the most effective way of hardfacing is
using flux cored arc welding. This additional material gives more possibilities to make expected hard surface layer.
Chemical composition, property and economic factors obtained in flux cored wire are much richer in comparison to these obtained with
other additional materials. This is the reason why flux cored wires give possibilities of application this kind of material for improving
surface in different sectors of industry.
In the present paper the imperfection in the layers was used for hardfacing process in different situations to show the possible application
in the surface layer. The work presents studies of imperfection of the welds, contains the picture of microstructures, macrostructures and
shows the results of checking by visual and penetrant testing methods.
The welding technologies are widely used for design of protection layer against wear and corrosion. Hardfacing, which is destined for
obtaining coatings with high hardness, takes special place in these technologies. One of the most effective way of hardfacing is using self
shielded flux cored arc welding (FCAW-S). Chemical composition obtained in flux cored wire is much more rich in comparison to this
obtained in solid wire. The filling in flux cored wires can be enriched for example with the mixture of hard particles or phases with
specified ratio, which is not possible for solid wires. This is the reason why flux cored wires give various possibilities of application of this
kind of filler material for improving surface in mining industry, processing of minerals, energetic etc. In the present paper the high
chromium and niobium flux cored wire was used for hardfacing process with similar heat input. The work presents studies of
microstructures of obtained coatings and hardness and geometric properties of them. The structural studies were made with using optical
microscopy and X- ray diffraction that allowed for identification of carbides and other phases obtained in the structures of deposited
materials. Investigated samples exhibit differences in coating structures made with the same heat input 4,08 kJ/mm. There are differences
in size, shape and distribution of primary and eutectic carbides in structure. These differences cause significant changes in hardness of
investigated coatings.
The application of hardfacing is one of the ways to restore the functional properties of worn elements. The possibility of using filler materials rich in chrome allows for better wear resistance than base materials used so far. The paper presents the results of research on the use of 3 different grades of covered electrodes for the regeneration of worn track staves. The content of the carbon in the covered electrodes was from 0,5% to 7% and the chromium from 5% to 33%. The microscopic and hardness tests revealed large differences in the structure and properties of the welds. The differences in the hardness of the welds between the materials used were up to 150 HV units. The difference in wear resistance, in the ASTM G65 test, between the best and worst materials was almost 12 times big.
The paper presents the capabilities of welding techniques to creating properties of wear resistant high chromium cast iron alloy. The use
of the right kind of welding sequence allows you to change the structure and properties of the obtained welds. Tests were conducted for
one type of additive material in the form of self shielded core wire. In order to determine the effect of the type of welding sequence on the
properties of welds performed welding using string bead and weave bead. The resulting weld was tested on hardness and research structure
in an optical microscope. In the following studies have been made erosive tests wear of made hardfacing. String beads gave structure rich
in carbides and harder about 270 HV of the weld with weave bead. Also, wear resistance was nearly twice as better for welds made with
string beads. In the experiment a decisive role in the resistance to wear plays a high hardness of the deposit and the presence of carbides in
its structure. Changes in the basic parameters of the deposition process allows for the formation of structure and properties of hardfacing
welds in a wide range.
Hot Isostatic Pressing elaboration of Norem02, an austenitic-ferritic hypereutectoid stainless steel, leads to the formation of an austenitic matrix with a mixture of acicular M7C3 and globular M23C6 carbides. The sintering tests, carried out by using an AISI 304L container, showed that the final microstructure and the carbides’ distribution of the HIPed Norem02 are strongly influenced by the process parameters (heating and cooling rate, sintering time, holding temperature and pressure) and by the particles’ size, microstructure and phase distribution of the initial powder. The morphological, crystallographic and chemical analysis of the sintered samples were completed by comprehension of the diffusion phenomena at the Norem02/304L interface, enabling the establishment of a correlation between elaboration process and final microstructure.
Materials based on cast irons are often used for protection against wear. One of the methods of creating protective surface with cast iron structures is hardfacing. The application of hardfacing with self shielded flux cored wire with high carbon content is one of the economical ways often used to protect machinery parts exposed to both abrasion and erosion. The wear resistance of hardfacings depends on their chemical composition, structure obtained after hardfacing, parameters of depositing process and specific conditions of wear. As the base material in the investigation the steel grade S235JR was used. The wear behavior mechanism of hardfacings made with one type of self shielded flux cored wire and different process parameters were evaluated in this paper. Structures obtained in deposition process were different in hardness, amount of carbides and resistance to wear with two investigated impingement angles. The erosion tests showed that impingement angle 30° gives lower erosion rate than angle 60°.