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COORDINACIÓN DE REVISTAS INSTITUCIONALES | UACh

e-ISSN: 2007-4026 / ISSN print: 2007-3925

Ingeniería Agrícola y Biosistemas

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Home / Articles / Vol. 10 - 1 - 2018

Volume 10, Issue 1, Enero-Junio 2018

  

Volume 10, Issue 1, Enero-Junio 2018



doi: 10.5154/r.inagbi.2017.01.002
Fecha de publicación: 2018-02-13
Determination of shear velocity in a mild-sloping open channel flow
Ángel Mendoza-González; Ariosto Aguilar-Chávez

Keywords: esfuerzo cortante, velocimetría acústica de efecto Doppler, ley logarítmica

Objective: To present a methodology that allows experimentally determining shear velocity, considering the log-law as a model of velocity distribution in the outer region of turbulent flow. 
Methodology: The experimental study was carried out in a rectangular-shaped, variablysloped channel with a 0.245-m-wide base and 5 m long. Flow velocity was measured with an Acoustic Doppler Velocimeter (ADV), and the measurement area was 12 mm. Shear velocity was determined by the instantaneous velocity equation (ui,j). 
Results: The log-law model had a good statistical fit with the shear velocity estimated from the experimental data.
Study limitations: The experimental tests were conducted only in subcritical regime with low aspect ratios. In addition, in all tests, the measurement of instantaneous velocities was carried out only in a 12-mm profile, as close as possible to the wall.
Originality: The model to calculate the shear velocity is presented explicitly, and the statistical approach employed supports the use of the median as an estimator of the shear velocity.
Conclusions: The presented methodology shows low uncertainty in the estimation of shear velocity. The Anderson-Darling test showed that the results do not follow a normal distribution, so the median is the statistical parameter to define the shear velocity value.



doi: 10.5154/r.inagbi.2017.10.014
Fecha de publicación: 2018-06-27
Classical thermodynamic-based models for predicting physical properties of a biodiesel fuel
José E. Benavides-Fajardo; Mauricio Romero-Bastida; Felipe A. Perdomo; Ma. Del Carmen Núñez-Santiago

Keywords: biofuel, Peng-Robinson equation, simulation, second-order properties.

Objective: To obtain a model based on the classical Peng-Robinson equation of state (PR-EOS) to evaluate the initial thermodynamic expressions (first- and second-derivative properties) in biodiesel.
Methodology: A modified temperature dependence was used to transform the volume of the Peng-Robinson cubic equation of state to predict the thermophysical properties of biodiesel. The fuel studied is composed of five fatty acid methyl esters (methyl palmitate, stearate, oleate, linoleate and linolenate), which are the primary constituents of biodiesel.
Results: The results showed that the approach presented in this work can improve the prediction of secondorder properties (isentropic bulk modulus, heat capacities and speed of sound) if the accuracy of the primary properties is maintained (vapor pressure and liquid density).
Study limitations: Biodiesel is highly corrosive and is used in mixtures with other fuels such as gasoline; however, the model is only applicable to the properties of biodiesel and not mixtures.
Originality: Two concepts in the Peng-Robinson equation are used: the α(T) function and volume transformation. The second concept was implemented because second-order thermodynamic properties need accurate densities and derivatives with respect to the total volume. Additionally, the α(T) function was selected through a systematic search among a wide range of reported correlations.
Conclusions: The proposed thermodynamic model can predict, with only a few experimental data, properties that have an impact on the representation of spray, atomization and combustion events in diesel engines.



doi: 10.5154/r.inagbi.2017.07.012
Fecha de publicación: 2018-06-27
Kinematic wave hydrologic model of the Turbio River basin, Guanajuato, Mexico
Gregorio Vargas-Castañeda; Laura A. Ibáñez-Castillo; Ramón Arteaga-Ramírez; Gustavo Arévalo-Galarza

Keywords: rainfall-runoff, flood routing, unit hydrograph, flood warning model.

Objective: To apply the HEC-HMS methodology based on kinematic wave theory in the Turbio river basin to increase the accuracy of the model in predicting storm runoff.
Methodology: Calculations were made for: 1) rainfall depth to runoff depth, through the Soil Conservation Service (SCS) runoff curve number method, 2) runoff depth to hydrograph, for which the SCS unit hydrograph method and kinematic wave (KW) method were used, 3) flood routing in channels, by the Muskingum and KW methods, and 4) flood routing in dams, with the mass balance method. All steps were executed with the HEC-HMS program. Combinations and comparisons of methods 2 and 3 were made, while 1 and 4 remained constant.
Results: The hydrologic model that presented the highest Nash-Sutcliffe efficiency index (NSE) was the KW-Muskingum combination, where the runoff depth becomes a hydrograph through the KW and the flood routing in channels is carried out with the Muskingum method, and the lowest value was shown by the KW-KW combination.
Study limitations: The models were calibrated for only one event, due to the simultaneous availability of sub-hourly rainfall and flows. This limitation implies that subsequent efforts should focus on validating the kinematic wave model.
Originality: The hydrologic model presented here is by events and could be implemented in a flood early warning system.
Conclusions: According to the NSE, the three methods were satisfactory; however, the best was the KW-Muskingum combination.


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