Ciencias Exactas y Ciencias de la Salud
Permanent URI for this collectionhttps://hdl.handle.net/11285/551039
Pertenecen a esta colección Tesis y Trabajos de grado de las Maestrías correspondientes a las Escuelas de Ingeniería y Ciencias así como a Medicina y Ciencias de la Salud.
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- Road load data acquisition system with SAE-J1939 communications network: integration and laboratory test(Instituto Tecnológico y de Estudios Superiores de Monterrey, 2018-05-14) Orellana Cruz, Oscar; Rodríguez González, Ciro Ángel; Siller Carrillo, Héctor Rafael; Martínez Romero, Oscar; Guedea Elizalde, FedericoThis thesis discloses the results of a reliability analysis (R&R Study) through comparative method to validate a data acquisition (DAQ) system developed and built as a prototype. The laboratory conditions were established in order to test and validate the prototype when it acquires signals from accelerometers and strain gages as well as parameters taken from the electronic control unit (ECU), in this case a truck. The prototype equipment is composed of 9030 Compact RIO system with NI 9862 module for Controller Area Network (CAN) SAE J1939 and NI 9206 for analog inputs. 800 Hz sampling rate is programmed with LabVIEW code to acquire, store and analyze information. For the truck parameters, the code developed by Armando Ramírez in his research [6] was replicated and integrated into the code developed for the acquisition of signals with a user-friendly and versatile interface. The parameters are accelerator pedal position, engine speed, engine coolant temperature and wheel-based vehicle speed, with these parameters is possible to analyze the driving mode during the road tests. Instrumentation for acceleration was developed on a shaker to acquire the data, the frequency and wave amplitude were controlled by the use of a signal generator and signal amplifier. The reference data is acquired by a Brüel & Kjaer (B&K) module model 3160-A pattern equipment with PULSE Time Data Recorder software. Instrumentation for strain measurements was developed by simulating the strain gage measurement using a variable precision resistor. The reference data is acquired by a B & K module model 3160-A pattern equipment with PULSE Time Data Recorder software and two multimeters: OTC 55 series and MUL-280. The analysis range for these measurements is 0 to 80 Hz. The selected equipment demonstrated the DAQ system capability to perform vibration and deformation measurements with a resolution of 0.1 g and 100 μɛ respectively in the frequency range from 0 to 80 Hz, as well as obtain parameters from CAN J1939 protocol at the same time.
- New Generation of 3D printed electrospray sources for microencapsulation in biomedical applications(Instituto Tecnológico y de Estudios Superiores de Monterrey, 2018-05-14) Benjamin de Jesus, Benjamín Evani; Zúñiga, Alex Elías; Olivera Trejo, Daniel; Martínez Romero, Oscar; García López, ErikaAdditive manufacturing by Digital Light Processor stereolithography (DLP-SLA) has shown a great potential to create high-density microfluidic devices due to it offers high resolution and relatively low-cost. In this work, the fabrication of 3D printed coaxial electrospray sources with a high density of emitters are reported by using DLP-SLA technology. The 3D printed electrospray sources have also proven to work correctly as a source of microencapsulation. To accomplish the objectives of the study, it was addressed in three sections primarily. First, the influence of the involved parameters on the final properties of printed microchannels was evaluated by the analysis and characterization of this promising additive manufacturing technology. Second, based on its maximum printing capabilities, multiplexed electrospray sources were designed. To manufacture suitable channels with diameters up to 160 µm, it was key to establish the smallest dimensions of the new devices, which were successfully printed with 41 and 57 coaxial emitters respectively. Finally, Vitamin D and alginate hydrogel were used to produce core-shell microparticles as an initial exploration in the encapsulation of biomedical substances via coaxial electrospraying. The accurate encapsulation was dependent on the flow rate, applied voltages, and mainly on the concentration of alginate solution.