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The purpose of this study is analysis of deformation and vibrations of turbine blades produced by high electrolyte pressure during electrochemical machining.

An experimental setup was designed, experiments were conducted and the obtained results were compared with the finite element results. The deformations were measured according to various flow rates of electrolyte. In finite element calculations, the pressure distribution created by the electrolyte on the blade surface was obtained in the ANSYS® (A finite element analysis software) Fluent software and transferred to the static structural where the deformation analysis was carried out. Three different parameters were examined, namely blade thickness, blade material and electrolyte pressure on blade disk caused by mass flow rate. The deformation results were compared with the gap distances between cathode and anode.

Large deformations were obtained at the free end of the blade and the most curved part of it. The appropriate pressure values for the electrolyte to be used in the production of blisk blades were proposed numerically. It has been determined that high pressure applications are not suitable for gap distance lower than 0.5 mm.

When the literature is examined, it is required that the high speed flow of the electrolyte is desired in order to remove the parts that are separated from the anode from the machining area during electrochemical machining. However, the electrolyte flowing at high speeds causes high pressure in the blisk blades, excessive deformation and vibration of the machined part, and as a result, contact of the anode with the cathode. This study provides important findings for smooth electro chemical machining at high electrolyte flows.

Today, the need for renewable energy is rising steadily. Various steps are being taken by nations to address the rising need. The developments occurring in proportion to the industrial structures and economic levels of the countries, these efforts, the political structure of the country, some established patterns from the past, and many other external factors affect the use of renewable energy and therefore sustainable development, which has been one of the most important agendas since the early 1990s. In this study, it is examined whether certain characteristics of the Scandinavian Welfare Model affect the background of this successful image of Finland, Denmark, and Sweden, which rank in the top three positions in both the Global Energy Innovation Index and the Sustainable Development Report. As a result, although the use of fossil fuels increases the ecological footprint in the Scandinavian countries, which are evaluated as in the rest of the world, continuing the principles of innovation, trust, equality, openness, and sustainability with determination, the Nordic approach has not departed from the welfare state principle compatible with its own codes, unlike the transformations experienced by other welfare regimes, and has become a distinctive factor.