Mechanical Engineering – ANSYS Fluent Training Package, 10 Practical Exercises for INTERMEDIATE Users (Part 2)
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Description
Mechanical Engineering – ANSYS Fluent Training Package, 10 Practical Exercises for INTERMEDIATE Users (Part 2)
There are 10 practical exercises in this training package by ANSYS Fluent software for Mechanical Engineers. This package presents how to simulate different mechanical devices for all INTERMEDIATE users.
In analysis number 1, the process of separating the liquid phase from the gas is using a horizontal cylindrical separator is investigated. The realizable k-epsilon model is used for solving turbulent flow equations. Also, a multi-phase VOF model is activated to simulate two phases of oil and hydrogen sulfide inside the separator. Problem number 2 simulates the collision of air and water flow within a separator chamber. In this modeling, a cylindrical separator chamber is designed whose interior space is full of water. Water then enters through a vertical pipe from the top of the chamber and exits through a bottom pipe located at the bottom of the chamber; While airflow enters from a horizontal tube on the lateral surface of the chamber and exits through a horizontal tube on the lateral surface of the upper part.
In project number 3, the moving of a sea robot is simulated. The water enters the inlet boundary with a velocity of 1.5m/s while the robot moves towards this boundary with a velocity of 3m/s. The dynamic mesh model is activated and smoothing and remeshing options are enabled.
In practical exercise number 4, the water flow passing over the Kaplan turbine is investigated. The Kaplan turbine rotates at 3300 rpm and sucks the water in. RNG k-epsilon model is exploited to solve turbulent flow equations. It should be noted that the MRF (Frame Motion) option has been activated to model the rotation of the turbine. In project number 5, we are going to study the hydrodynamics of a Kaplan turbine. The geometry included a small size Kaplan turbine with 125 [mm] as a new prototype. Our static domain consists of 8 [m] long rectangle, and our rotary domain is the Kaplan geometry with 16.5 RPM as the angular velocity.
In project number 6, steady airflow mixing with fuel is investigated in a 3-outlet manifold where only one outlet is effective and the other 2 outlets are blocked. There are two inlets that provide air and fuel flow into the domain. Air and fuel flow rates are equal to 0.2335 and 0.0374 kg/s. Species entering the domain via air inlet are nitrogen and oxygen with mass fractions equal to 0.79 and 0.21, respectively.
Problem number 7 simulates fluid mixing in a bioreactor with a Rushton turbine. The bioreactor modeled in this simulation has a cylindrical structure. A stirrer is placed vertically inside it to rotate the fluid flow inside this model to help the fluid mix and thus the desired chemical process.
In project number 8, the analysis of thrust and lift forces behind the mechanical propeller on the fuselage is examined. A propeller consists of two or more twisted blades. The rotating computational domain must rotate around the impeller axis to model the impeller rotational motion using the Mesh Motion method.
In study number 9, using the DPM (Discrete phase material) method, the effect of impurities in a gas splitter was investigated. The impurity gas entered at a speed of 5 meters per second vertically and was directed out through 3 outlets. The impurity distribution, concentration, adsorption, and reflection in the installed filters are investigated.
Finally, In project number 10, a numerical effort has been used to simulate the agricultural drone sprayer. The system consists of two different fluids, including air as the primary fluid, and one secondary fluid is poison with a density of 0.9512. The Eulerian multiphase model has been used.
You can obtain Geometry & Mesh file and a comprehensive Training Movie that presents how to solve the problem and extract all desired results.
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