Journal of Engineering Sciences / Журнал інженерних наук
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Item Mechatronic system’s permeable materials with controlled porosity(Sumy State University, 2021) Povstyanoy, O.; MacMillan, A.Up-to-date directions in the development of modern industry increase the requirements for the quality of technical products. The design and manufacture of competitive process equipment require accuracy, productivity, and efficiency. Therefore, in this article, a new mechatronic system has been designed and developed to help porous, permeable materials with predicted porosity have been produced. The research aims to develop a mechatronic system for technology optimization in manufacturing permeable porous materials with controlled properties. As a result, the method of computer modeling of porous, permeable materials was developed. It allows us to consider the peculiarities of porosity distribution and radial velocity in radial isostatic compression. Additionally, a new mechatronic system for producing permeable materials allows us to determine the porosity distribution and particular characteristics of permeable powder material. The proposed approach allows us to evaluate the impact of technological modes on the main operational characteristics.Item Influence of technological manufacturing conditions on the porosity of calcium-phosphate scaffolds(Sumy State University, 2021) Chernobrovchenko, V.S.; Дядюра, Костянтин Олександрович; Дядюра, Константин Александрович; Diadiura, Kostiantyn Oleksandrovych; Balynskyi, M.; Panda A., A.The implantation of bone substitutes depends on the material’s osteoconductive potential and the structure's porosity Porosity is a characteristic feature of most materials. The porosity of materials has a strong influence on some of their properties, both structural and functional. An essential requirement for bone scaffolds is porosity, which guides cells into their physical structure and supports vascularization. The macroporosity should be large enough and interdependent for bone ingrowth to occur throughout the entire volume of the implant. The pore size for cell colonization in bioceramics is approximately 100 μm. Pores larger than this value promote bone growth through the material. This pore size allows the flow of growth factors and cell adhesion and proliferation, allowing the formation of new bone and developing the capillary system associated with the ceramic implant. Porosity also affects the rate of resorption of ceramics: the larger the number of micropores, the higher the dissolution rate. The investigated properties were elastic moduli, ultimate strength, compressive strength, and average apparent density. The results obtained in this work are consistent with previous studies, proving the positive role of microporosity in osseointegration and bone formation.