No 2 (2017)

The paper deals with the problems of designing and creating one of the types of jewelry - decorative jewelry box made of metal. A detailed description of the sequence of design-engineering - from the choice of subjects to its manufacture - is given. The relevance of the product being developed is proved; the analysis of the product analogues is carried out in terms of artistic and material design. An original sketch of decorative jewelry box corresponding to aesthetic, structural and functional design requirements with a regard to an analysis of the strengths and weaknesses of the existing analogues is developed. The ergonomic factors, suggesting the convenience of use of the product are taken into account when creating jewelry box. The choice of material is justified. On the basis of the material properties the production process is selected. The product weight is calculated and the structural analysis of the pivoted fall joint is made involving Inventor software product. The necessary drawings, the master model for investment casting are made. The decorative jewelry box production process consisting of three main phases: 1) the production of the jewelry box case, 2) applying a decorative coating, 3) assembling of the jewelry box elements is described. Molding technology for the production of a single product is considered. As a result of design-engineering a jewelry box based on the artistic image of the stylized giraffe’s figures with entwined necks is produced. The use of stylized figures of birds and animals for the production of small metal boxes adorned with enamel and precious inserts is a fashion trend at the moment.

The peculiarities of the behavior of the powder mixtures of metals and metal matrix composites during Spark Plasma Sintering (SPS) using Ti3SiC2-Cu, Fe-Ag, NiO-Ni, Cu2O-Cu, and Fe-Al systems as examples are analyzed in the work. The physical and chemical aspects of the formation of contacts between composite agglomerates obtained by mechanical treatment of the powder mixtures in a high-energy ball mill and the possibilities of the SPS method for the production of metal matrix composites combining different strengthening mechanisms are discussed. In the Ti3SiC2-Cu composites obtained by mechanical milling and SPS, the copper matrix remains in the nanocrystalline state, and the total contribution of dislocation and grain boundary strengthening is greater than the contribution of dispersion strengthening. Microstructural studies of the sintered Ti3SiC2-Cu and Fe-Ag compacts show that during SPS of mechanically milled powders, areas of inter-agglomerate contacts can experience melting. In the systems capable of interfacial interactions, the latter preferentially occur at the inter-agglomerate contacts. The conditions for the efficient reduction of oxide films present on the surface of metallic particles during the SPS using a partially oxidized copper powder containing Cu2O and a partially oxidized nickel powder containing NiO are examined. It is found that under the SPS conditions commonly used in the consolidation practice of metallic powders, elimination of oxide films present on the surface of metallic powders is due to chemical reduction of the oxides by carbon. It is experimentally shown, that reactive pressureless SPS can produce porous materials of high open porosity.

Impact machines are one of the most productive types of equipment for the rock destruction. They provide high drilling speed but generally have low durability and reliability. Modern researches show that the process of mining machines parts fracture often is initiated by nonmetallic inclusions and internal defects in the structure of steel. However, nowadays the question concerning the degree of the influence of the nonmetallic inclusions morphology, size, shape and distribution on the steel fatigue failure resistance is still not clear. The traditional approach to solving the problem of the inclusions influence on steel properties requires the preparation of a significant number of experimental samples, so mathematical modeling is a promising method for assessing the influence of nonmetallic inclusions. The purpose of the research was to estimate the stresses intensity field near nonmetallic inclusions under the influence of cyclic compressive stresses and to develop recommendations for the usage of steels with various impurities for the impact machines parts manufacture. The effect of nonmetallic inclusions under dynamic loading conditions was evaluated in several stages. At the initial stage, using the methods of metallographic and microspectral analysis, the size, shape and morphology of nonmetallic inclusions in ten melt of 45 steel were determined. The obtained results were used as input data for the software package ANSYS Workbench 15.0 for calculating the stress field intensity the near inclusions. The reliability of the obtained mathematical models was checked by measuring the internal stresses by the X-ray diffraction analysis with ARL X'TRA diffractometer. Metallographic studies have shown that the main types of inclusions in the steel are point oxides, whose size can reach up to 100 microns and plastic sulphides up to 1.mm in length. The results of numerical simulation show that under dynamic compression conditions an application of the approach in which the inclusion is assumed to be mechanically equivalent to the pore or crack is incorrect. Under the dynamic compression condition near the pores and low-strength inclusions in the base material regions with a high level of local stresses are formed. The maximum value of the equivalent stresses was revealed near the elongated defects in the case of their orientation perpendicular to the action of the external force. Stress distribution near hard and strong oxides inclusions is significantly different. The maximum stresses are localized in the inclusion, while the stress magnitude is insignificant in the boundary region between the inclusion and base material. To verify the reliability of the data of the numerical experiment, XRD analysis was used for zonal stresses measuring. The results of X-ray diffractometry confirm the assumption that under compression conditions the presence of pores in the steel and plastic low-strength inclusions leads to a 50 % increase of local stresses of the main material near the defects. The stress level near the solid high-strength inclusions in the base material is 20 % lower than the average level. The results of the research show that it is desirable to make the details of impact machines using the steels whose structure contains inclusions which hardness exceeds the hardness of the matrix or apply high-purity steels with a low content of nonmetallic inclusions.