Maestría en Mecánica Mención Diseño
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Item Análisis de la aleación mecánica de aluminio 1060 con porcentajes controlados en peso de zinc y su incidencia en la resistencia última a la tensión, dureza e impacto(Universidad Técnica de Ambato. Facultad de Ingeniería Civil y Mecánica. Maestría en Mecánica Mención Diseño, 2019) Pineda Silva, Giovanny Vinicio; López Villacís, Gonzalo EduardoThe research project begins due to the need to have technically documented information related to powder metallurgy within the scope of mechanical alloy, manufacturing process that is entering into the National Industry, due to the advantages it presents with respect to traditional processes; being the most representative, a more exact control of the limits of the composition, optimization of raw material and is a process susceptible to automation with good surface finish for serial production of mechanical components. The experimental process of the mechanical alloy begins with the obtaining of mechanical powder of the base elements: Aluminum 1060 with particle size 30 micrometers and alloying: Zinc with particle size between 45−63 micrometers through the use of ball mill and a screening control; mixing process based on the percentages in weight defined for the subsequent compaction and sintering of the test pieces for the correct development of the tests. The study of tensile strength, hardness and impact was developed though the control of variables of percentage by weight of alloying element: 0.5 – 1.0 y 1.5 percentage Zinc, and sintering temperature: 462 celcius degrees y 594 celsius degrees ; the best results were obtained in the case of a study developed with 1 percentage Zinc and a temperature of 594 celsius degrees, where the hardness and tensile strength were increased by 69 percentage and 12.29 percentage respectively in relation to the base element; while the impact resistance as a function of the energy absorbed decreases by 39.40 percentage in the best case 1 percentage Zinc and 462 celsius degrees; in addition, the controlled variables are correlated with each other and directly affect the properties under study according to the statistical analysis developed by Fisher’s test.Item Estudio de la influencia del proceso de soldadura del acero HSLA ASTM A500 GR C utilizado en carrocerías de buses en sus propiedades mecánicas(Universidad Técnica de Ambato. Facultad de Ingeniería Civil y Mecánica. Maestría en Mecánica Mención Diseño, 2020-09) Carrasco Carrasco, Luis Roberto; López Villacís, Gonzalo EduardoThis research is intended to define the influence of the heat contributed by the welding process of the bus bodywork on the properties of the material and its capacity of resistance to impact, and for this purpose it began with the testing of ASTM A500 steel without welding. Then, the test was carried out with the E6011 electrode central weld and with the ER70S-6 electrode, measuring the deformation with an initial length of 100mm. It can be effectively verified that the welding process does affect the properties of the material. The most affected property was the modulus of elasticity with a change that exceeded 80 percent, which means that the welding process modified the material making it more rigid and brittle due to the change in temperature and the cooling rate. The yield stress of the material in the welded area decreased to 10 percent, which also reduces the safety factor in this area. Following this, the impact simulation of the front of the bus bodywork was modeled and performed by using the results of the tests in the welding area. The simulation results allowed to identify the areas where the greatest stresses occur, these were located in the area of the frontal collision near the welded joints, but not on the welds. The stress in these areas exceeded the maximum yield stress, but the percentage deformations were less than the tests without breaking the structure.