Resumen
La electrónica impresa usa tintas especiales para crear dispositivos electrónicos en sustratos diversos. Es una opción tecnológica económica e inmediata, cuya investigación está en constante desarrollo, lo que abre puertas para aplicaciones en sectores existentes y emergentes. En este trabajo se exploran las posibilidades de desarrollo de componentes básicos (resistencias y capacitores) impresos basados en impresión 3D así como las metodologías para el diseño y posterior verificación de los mismos. En la sección resultados se exploran las diferentes topologías de los componentes impresos pudiéndose observar los parámetros más relevantes y sus variaciones respecto a sus dimensiones.
Las conclusiones confirmaron que la resistividad del material varía antes y después de la extrusión. Los condensadores impresos fusionados en una impresora 3D permitieron calcular la permitividad relativa del dieléctrico y extrapolar valores para otros tamaños de condensadores. La impresión 3D de circuitos se ve como una alternativa viable para prototipos económicos en resistencia y capacitores.
Palabras Clave: Acido Poliláctico, Bajo costo, Componentes impresos, Electrónica impresa, Impresión 3D.

Abstract
Printed electronics use special inks to create electronic devices on various substrates. It is an economical and immediate technological option, whose research is constantly evolving, opening doors for applications in existing and emerging sectors. This work explores the development possibilities of basic components (resistors and capacitors) printed based on 3D printing, as well as the methodologies for their design and subsequent verification. The results section explores the different topologies of printed components and their most relevant values, allowing for the observation of the most significant parameters and their variations with respect to their dimensions.
The conclusions confirmed that the resistivity of the material varies before and after extrusion. Printed capacitors fused in a 3D printer allowed for the calculation of the relative permittivity of the dielectric and extrapolation of values for other capacitor sizes. 3D printing of circuits is seen as a viable alternative for cost-effective prototypes in resistors and capacitors."
Keywords: 3D printing, Low cost, Polylactic acid (PLA), Printed components, Printed electronics.

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