Identificador persistente para citar o vincular este elemento: http://hdl.handle.net/10553/129322
Título: Venturi Injector Optimization for Precise Powder Transport for Directed Energy Deposition Manufacturing Using the Discrete Element Method and Genetic Algorithms
Autores/as: Garcia Montagut, Carlos Joshua 
Paz Hernández, Rubén 
Monzón Verona, Mario Domingo 
González Landín, Begoña 
Clasificación UNESCO: 331005 Ingeniería de procesos
3303 ingeniería y tecnología químicas
Palabras clave: Additive Manufacturing
Directed Energy Deposition
Discrete Elements Modeling
Genetic Algorithms
Powder Transport, et al.
Fecha de publicación: 2024
Publicación seriada: Materials 
Resumen: Additive manufacturing technologies such as directed energy deposition use powder as their raw material, and it must be deposited in a precise and controlled manner. Venturi injectors could be a solution for the highly precise transport of particulate material. They have been studied from different perspectives, but they are always under high-pressure conditions and mostly fed by gravity. In the present study, an optimization of the different dimensional parameters needed for the manufacturing of a Venturi injector in relation to a particle has been carried out to maximize the amount of powder capable of being sucked and transported for a specific flow in a low-pressure system with high precision in transport. For this optimization, simulations of Venturi usage were performed using the discrete element method, generating different variations proposed by a genetic algorithm based on a preliminary design of experiments. Statistical analysis was also performed to determine the most influential design variables on the objective, with these being the suction diameter (D3), the throat diameter (d2), and the nozzle diameter (d1). The optimal dimensional relationships were as follows: a D3 34 times the particle diameter, a d2 26.5 times the particle diameter, a d1 40% the d2, a contraction angle alpha of 18.73°, and an expansion angle beta of 8.28°. With these proportions, an 85% improvement in powder suction compared to the initial attempts was achieved, with a maximum 2% loss of load.
URI: http://hdl.handle.net/10553/129322
ISSN: 1996-1944
DOI: 10.3390/ma17040911
Fuente: Materials[EISSN 1996-1944],v. 17 (4), (Febrero 2024), p. 1-23
Colección:Artículos
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